effect of building materials cost on housing delivery
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i
EFFECT OF BUILDING MATERIALS COST ON HOUSING DELIVERY TOWARDS
SUSTAINABILITY
by
BIMPE ALABI
Thesis submitted in fulfilment of the requirements for the degree
Master of Construction: Construction Management
in the Faculty of Engineering
at the Cape Peninsula University of Technology
Supervisor: Dr. Fapohunda J.A.
Bellville Campus
October 2017
CPUT copyright information
The thesis may not be published either in part (in scholarly, scientific or technical journals),
or as a whole (as a monograph), unless permission has been obtained from the University.
ii
DECLARATION
I, BIMPE ALABI, declare that the contents of this thesis represent my own unaided work,
and that the content has not previously been submitted for academic examination towards
any qualification. Furthermore, it represents my own opinions and not necessarily those of
the Cape Peninsula University of Technology.
--------------------------------------------- ----------------------------
Signed Date
iii
ABSTRACT
The study investigates the predominant factors responsible for increase in the cost of
building materials and the effect of this cost increase on housing delivery in Western Cape,
South Africa.
Sustainable housing is buildings produced to meet the present housing needs of people
without conceding the ability of the future generation to meet their future needs. However, a
significant increase in the cost of building materials has been a major constraint to the
delivery of sustainable housings, as made evident in the literature, leading to project cost
and time overruns or even project abandonment. However, building materials consume up to
65% of the total cost of construction. This factor on cost has, over the years, threatened the
ability of the construction industry to deliver projects within budgeted cost, at stipulated time,
and at satisfactory quality. This prompted the need to proffer solutions to these factors
identified which are causing increases in the cost of building materials towards sustainable
housing delivery in Western Cape. Based on this research study, housing is termed to be
sustainable when it is available and affordable for the masses timely and at quality expected.
The research study adopted a mixed methodological approach, involving the use of semi-
structured qualitative interviews and closed-ended quantitative questionnaires administered
to construction stakeholders (architects, quantity surveyors, engineers, construction
managers, project managers, site supervisors and material suppliers) in the Western Cape
Province of South Africa. SPSS version 24 software was used for analysing the quantitative
data collected and ‘content analysis’ method was used to analyse the information collected
through the qualitative interviews.
iv
The findings revealed that the major factors responsible for increasing the cost of building
materials are inflation, wastages of building materials by labourers, cost of transportation
and distribution of labour, design changes, client contribution to design change and change
in government policies and regulation. Moreover, the research showed that fluctuation in the
cost of construction and high maintenance costs due to poor workmanship also impact the
cost increase of building materials for housing delivery. In addition, research findings
affirmed that for optimum materials usage for the enhancement of sustainable construction,
the following criteria should be considered in the selection of building materials: maintenance
cost, energy consumption and maintainability.
The adoption of these findings by construction stakeholders in the South African construction
industry would enhance the delivery of affordable housing at reduced cost, at the required
time and at the expected quality. Therefore, an adequate implementation of the framework
presented in this study will enhance sustainable housing delivery.
Keywords: Building materials, housing, housing delivery, material cost, stakeholders,
sustainability and sustainable housing.
v
ACKNOWLEDGEMENTS
•I acknowledge the mercy and the grace of the Almighty God upon my life during the course
of this study.
•I acknowledge the helpful guidance of my supervisor, Dr. Julius Ayodeji Fapohunda, for his
inestimable guidance, encouragement and inspiration for success of this study.
•To CPUT Head of Department, Mrs. Toni Stringer, and the entire staff of the Construction
Management Department.
•My greatest blessing, family – my son Malcolm Jeje; my parents; my siblings and their
spouses – for their spiritual, financial and moral support throughout the course of this study.
•To Dr. Pastor and Mrs Oduwole, Pastor and Mrs Oba, Mr Ayodele and family, and
members of RCCG Victory Tabernacle. I appreciate you for the encouragement, prayers and
love you shared with me in the course of the study.
•My reviewers and senior friends; Dr. Bashir Alaanu (CPUT), Mr. Fred Simpeh (CPUT), Mr.
Eric Simpeh (CPUT), Dr. Lance Wentzel and Mr. Imisioluseyi Julius for their invaluable
inputs in this piece of work.
•My colleagues – Iyiola Bolumole, Mariam Akinlolu, Thasi Fedi, Alvin Opperman, Musa
Ngqongisa, Fisher and Anzola Mayoza – for ensuring an enabling work environment through
the course of the study.
• Gratitude goes to more of my family and friends who has been supportive – Pastor and Mrs
Adegoke, Mr and Mrs Babatope, Dr. and Mrs Ogunsina, and Dr. and Mrs Dania, Musa
Sefinat – for all the assistance during this study.
vi
DEDICATION
This thesis is dedicated to Temitope Jeje.
vii
TABLE OF CONTENTS
DECLARATION ......................................................................................................................................... ii
ABSTRACT ............................................................................................................................................... iii
ACKNOWLEDGEMENTS ........................................................................................................................... v
TABLE OF CONTENTS ............................................................................................................................. vii
LIST OF FIGURES ...................................................................................................................................... x
LIST OF TABLES ....................................................................................................................................... xi
DEFINITION OF TERMS .......................................................................................................................... xii
ABBREVIATIONS AND MEANING .......................................................................................................... xiii
ARTICLES FOR PUBLICATION .................................................................................................................xiv
CHAPTER ONE ......................................................................................................................................... 1
1.1 INTRODUCTION ....................................................................................................................... 1
1.2 BACKGROUND TO THE STUDY ............................................................................................. 2
1.3 Problem statement ............................................................................................................. 4
1.4 AIM AND OBJECTIVES OF THE RESEARCH ........................................................................... 4
1.4.1 Aim .................................................................................................................................. 4
1.4.2 Objectives ........................................................................................................................ 5
The objectives of this research are as follows: ............................................................................... 5
1.5 Research questions ............................................................................................................. 5
1.6 Significance of the study ..................................................................................................... 5
1.7 Research methodology and design ..................................................................................... 6
1.7.1 Research design .............................................................................................................. 6
1.7.2 Population of the study ................................................................................................... 7
1.7.3 Instrument for data collection ........................................................................................ 7
1.7.4 Administration of instrument ......................................................................................... 8
1.7.5 Techniques of data analysis ............................................................................................ 8
1.7.6 Scope and limitation of the study ................................................................................... 8
1.8 Key assumptions ................................................................................................................. 8
1.9 Ethical considerations ......................................................................................................... 9
1.10 Thesis structure ................................................................................................................... 9
1.11 Research process .................................................................................................................... 9
1.12 Chapter summary...................................................................................................................... 10
2.0 LITERATURE REVIEW ....................................................................................................................... 11
viii
2.1 Introduction .......................................................................................................................... 11
2.2 Construction industry ........................................................................................................... 11
2.2.1 Construction stakeholders ................................................................................................... 13
2.3 Sustainable development and sustainable housing ................................................................... 14
2.4 Building materials ....................................................................................................................... 16
2.4.1 Factors responsible for increase in the cost of building materials ...................................... 17
2.4.1.2 Building production related factors .................................................................................. 19
2.4.1.3 Stakeholder related factors .............................................................................................. 21
2.4.1.4 External factors ................................................................................................................. 22
2.5 Construction project consideration ............................................................................................ 23
2.5.1 Cost consideration ............................................................................................................... 24
2.5.2 Quality consideration ........................................................................................................... 25
2.5.3 Time consideration .............................................................................................................. 26
2.5.4 Human management ........................................................................................................... 27
2.6 Material management ................................................................................................................ 28
2.6.1 Materials utilisation and wastage ........................................................................................ 30
2.6.2 Waste management ............................................................................................................. 31
2.6.3 Cost overrun in construction project ................................................................................... 32
2.6.4 Time overrun in construction project .................................................................................. 33
2.7 EFFECTS OF BUILDING MATERIALS COST ON HOUSING DELIVERY ............................................. 35
2.7.1 Fluctuation in cost of construction ...................................................................................... 35
2.7.2 Increase in project abandonment. ....................................................................................... 36
2.7.3 Low volume of construction product ................................................................................... 36
2.7.4 Poor quality of workmanship ............................................................................................... 37
2.7.5 Unemployment of construction workers ............................................................................. 37
2.8 Selection of sustainable building materials ................................................................................ 38
2. 8.1 Principles of material selection towards sustainable construction .................................... 39
2.8.2 Criteria for selection of sustainable building materials ....................................................... 41
2.8.2.1 Resource efficiency ........................................................................................................... 42
2.8.2.2 Energy efficiency ............................................................................................................... 42
2.8.2.3 Indoor Air Quality (IAQ) .................................................................................................... 43
2.9 Chapter summary............................................................................................................................ 44
CHAPTER THREE .................................................................................................................................... 45
RESEARCH METHODOLOGY AND DESIGN ............................................................................................. 45
ix
3.1 INTRODUCTION ............................................................................................................................... 45
3.2 Research philosophies .................................................................................................................... 45
3.3 Research methodology ................................................................................................................... 47
3.4 Research approach.......................................................................................................................... 51
3.5 Research strategies ......................................................................................................................... 52
3.6 Questionnaire development ........................................................................................................... 54
3.7 Research design .............................................................................................................................. 56
3.8 Validity and reliability of the data ................................................................................................... 62
3.9 Chapter summary............................................................................................................................ 63
CHAPTER FOUR ..................................................................................................................................... 65
4.1 Introduction ................................................................................................................................ 65
4.2 Exploratory study ............................................................................................................................ 65
4.3 Questionnaire survey for the main study ....................................................................................... 65
4.5 Testing the reliability of the research Instrument .......................................................................... 71
4.6 Presentation of findings .................................................................................................................. 71
4.7 Discussion of the findings ............................................................................................................... 81
4.8 Validity assurance of the quantitative research results ......................................................... 89
4.9 Validation of findings .............................................................................................................. 90
4.10 Achieving the objectives of the research study ............................................................................ 96
4.11 Operational framework ........................................................................................................ 99
4.12 Chapter summary........................................................................................................................ 100
CHAPTER FIVE ..................................................................................................................................... 102
SUMMARY, CONCLUSIONS AND RECOMMENDATIONS ..................................................................... 102
5.1 Introduction .................................................................................................................................. 102
5.2 Summary ....................................................................................................................................... 102
5.3 Conclusion ..................................................................................................................................... 103
5.4 Limitations ..................................................................................................................................... 104
5.5 Conclusion and recommendations ............................................................................................... 105
5.6 Areas for further study.................................................................................................................. 107
REFERENCES ........................................................................................................................................ 108
APPENDICES: APPENDIX A – SURVEY QUESTIONAIRE......................................................................... 134
APPENDIX B: INTERVIEW QUESTIONS ................................................................................................. 144
x
LIST OF FIGURES
Figure 1.1: Conceptual framework ......................................................................................................... 4
Figure 1.2: Research process ................................................................................................................ 10
Figure 2.1: Sustainable development triangle ...................................................................................... 15
Figure 2.2: Managerial processes in construction project management ............................................. 24
Figure 2.3: Model for continuous improvement of construction productivity .................................... 27
Figure 2.5: The building materials life cycle phases.............................................................................. 39
Figure 2.6: Evaluation indicators of material selection ........................................................................ 41
Figure 3.1: Deductive and inductive research approaches ................................................................... 52
Figure 3.2: Research methodology ....................................................................................................... 64
Figure 4.1: Participants’ companies ...................................................................................................... 66
Figure 4.2: Respondents’ age group ..................................................................................................... 68
Figure 4.3: Highest formal qualifications .............................................................................................. 68
Figure 4.4: Position of the respondents ................................................................................................ 69
Figure 4.5: Years in present position .................................................................................................... 70
Figure 4.6: Operational frameworks for enhancement of sustainable housing delivery ................... 100
xi
LIST OF TABLES
Table 1.1 Relationship between research objectives, research questions and research methods Error!
Bookmark not defined.
Table 2.1: Factors responsible for cost and time overrun .................................................................... 34
Table 2.2: Main effects of cost overrun in construction projects through previous studies ................ 35
Table 3.1: Advantages and disadvantages of survey methods ............................................................. 48
Table 3.2: Comparison between qualitative and quantitative research .............................................. 49
Table 3.3 Strengths and challenges of mixed methods ........................................................................ 51
Table 3.4: Questionnaire design ........................................................................................................... 61
Table 4.1: Respondents’ gender ........................................................................................................... 67
Table 4.2: Experience of respondents in the construction industry ..................................................... 70
Table 4.3: Reliability of research instrument ........................................................................................ 71
Table 4.4: Economic related factors ..................................................................................................... 72
Table 4.5: Building production related factors responsible for increase in cost of building materials 74
Table 4.6: Stakeholder related factors responsible for increase in the cost of building materials ...... 75
Table 4.7: External factors responsible for increase in the cost of building materials ......................... 76
Table 4.8: Effects of increase in the cost of building materials on housing delivery ............................ 77
Table 4.9: Influence of stakeholders in materials selection ................................................................. 78
Table 4.10: Guidelines to material selection in construction towards enhancing sustainable building
delivery .................................................................................................................................................. 79
Table 4.11: Sustainable criteria for building materials selection .......................................................... 80
Table 4.12: Project factors .................................................................................................................... 81
Table 4.13: Summary of findings of quantitative data ......................................................................... 88
Table 4.13: Demographic of qualitative respondents .......................................................................... 91
Table 4.14: Summary of qualitative interviews .................................................................................... 96
Table 5.1: Summary of research study ............................................................................................... 102
xii
DEFINITION OF OPERATIONAL TERMS
BUILDING MATERIALS: Building materials are any materials used in the erection of a
building.
HOUSING: Housing is defined as any building or shelters that people live or a place of
dwelling.
HOUSING DELIVERY: This is the process of supplying sustainable housing, at affordable
cost and to a specified quality standard.
MATERIAL COST: This is the total cost of building materials (including purchase, handling
and logistics).
STAKEHOLDERS: These are groups of individuals (internal and external participants) who
work together to build, with the purpose of achieving the same objectives towards project
delivery.
SUSTAINABILITY: Is the state in which available components of the ecosystem and their
functions are maintained for the present and future generations.
SUSTAINABLE HOUSING: This is housing that is affordable and available to the present
and future generation.
xiii
ABBREVIATIONS AND MEANING
4Ms: Money, Manpower, Machine and Materials
4Rs: Renewable, Reusable, Recyclable and Reduction
CDW: Construction Demolition Waste
CIDB: Construction Industry Development Board
FIFA: Federation International De Football Association
FMEA: Failure Mode & Effect Analysis
GDP: Gross Domestic Product
GHG: Greenhouse Gas
IAQ: Indoor Air Quality
ISO: International Organisation for Standards
LCA: Life Cycle Assessment
LCC: Life Cycle Cost
PMBOK: Project Management Body of Knowledge
QIM: Quality Inspection and Management
SPSS: Statistical Package for Social Science
TQM: Total Quality Management
VOC: Volatile Organic Compounds
xiv
ARTICLES FOR PUBLICATION
Effects of increase in the cost of building materials on the delivery of affordable
housing in South Africa.
Factors responsible for increase in the cost of building materials that hinder
sustainable housing delivery.
1
CHAPTER ONE
1.1 INTRODUCTION
Previous studies in building sector have indicated that building materials account for
between 50 to 60% of the total construction input (Adedeji, 2012:1; Ogunsemi, 2010:2).
Building materials constitute the largest single input in building construction, of which
housing is one part. Adedeji (2012:2) revealed that the cost of building materials has been
one of the factors prohibiting successful housing delivery. Nega (2008) opine that increase in
costs of construction is caused by increase in the cost of building materials, an increase
which has a significant impact on overall budgeted cost of construction. Construction cost
has been the most significant consideration for the execution of any construction project.
Previous studies have determined that delays in housing deliveries have resulted in client
and contractor disputes, litigations and project abandonment, and cost and time overrun.
Hence, there is a need to address this increase in the cost of building materials that are
impeding the delivery of sustainable affordable housing that in the Western Cape of South
Africa.
While excessive costs of building materials has significantly slowed down the housing
delivery, nevertheless, the problem of increase in the cost of building materials cannot, be
rationally minimised by using non-conventional building materials, without due consideration
of the sustainability of these alternative materials, the appropriate initiative and the cost of
processing. The theory of sustainability has called for major attention in the construction
industry over recent decades.
Housing availability is characterized by its method of production as well as life cycle which
enhances the economic stability of the inhabitants by taking into consideration – at every
stage of construction – the use of land and materials resources (Solanke, 2015:2). Thus, to
deliver sustainable housing, it is crucial to consider the implications of cost of materials and
the resource availability (sustainability) from the housing design stage to construction stage
in order to ensure adequate building materials’ utilisation.
Thus, this research study provides information on the implication of increase in cost of
building materials by examining its influence on the construction industry and the effect on
sustainable and affordable housing delivery, and in order to proffer possible solutions for
minimising cost of building materials to perpetuate sustainable housing delivery in the
Western Cape, and all of South Africa at large.
2
1.2 BACKGROUND TO THE STUDY
Housing is a key factor in the sustainable development of a nation and a basic human need
(Ganiyu, 2016:2). Developing nations are continuously challenged with issues of inadequate
housing (du Plessis, 2002:1). Housing demand continues to grow in recent periods
worldwide and is projected to continue escalating (Wood, 2007). Ganiyu (2016:2) stated that
the benefits of sustainable buildings are more than just reducing the negative impact of
buildings on public health, but rather buildings must be cost effective, improving occupant
efficiency and enabling community development. Cost plays a significant role in making
decisions for the execution of sustainable construction (Kunzlik, 2003:185; Meryman &
Silman, 2004:217). Ofori and Kien (2004) stressed that the additional cost required in many
cases was the major constraint for sustainable construction implementation. Adedeji (2014)
also revealed that cost of building materials has been a major constraint for sustainable
housing delivery.
Building materials can amount to 50% of the total cost of all projects in the construction
industry (Agapiou et al., 1998:132). While building material cost is subject to demand and
supply, it is also affected by many other factors, including quality, quantity, time, place, buyer
and seller. However, more factors affecting cost of building materials include currency
exchange, material specification, inflation pressure and availability of new materials in the
country (Elinwa & Silas, 1993:699). Furthermore, the total cost of project is influenced by
various factors such as improper material handling and management on site during
construction production processes, all of which impact the time and quality of the project
(Che et al., 1999:70).
Ogunlana, Promkuntong and Jearkjirm (1996:40) are of the opinion that project deliveries
are delayed primarily as a result of incomplete construction drawings, material management
inefficiency, material wastages and site worker inefficiencies. Therefore, material
management in construction has been a source of critical concern to contractors for decades
(Linden & Josephson, 2013:91) and thus necessitates effective material management in
controlling productivity and cost (Kasim et al., 2005:794). Similarly, Solanke (2015:4)
suggested that the utilisation of material tactics helps in attaining orderliness and avoids
material wastages on construction sites. The literature reviewed revealed that materials
wastages on construction sites are a result of excessive purchase of materials, extended
storages, material abandonment and unclear design specifications during production. Thus,
it is high priority that material resources be managed properly to reduce waste, and achieve
timely project delivery at the budgeted cost and acceptable quality.
3
Asif et al. (2008) described sustainability as the ability to meet present needs of stakeholders
without impeding on the future quality of life due to extreme use of ecological resources,
social impact and economic loss in a region. In order to meet the housing demand, the
developments must be affordable and sustainable as well, thereby making smart use of
sustainable building materials. The prerequisite for undertaking any development is that the
products are functional and economically cost effective and available within the shortest time
(Ihuah, 2015:219). Conversely, persistent increases in the cost of building materials is
projected to work against this, as this increase in cost of building materials affects the
current demand greater than the available supply, so some development projects are then
abandoned and left uncompleted (Ihuah, 2015:219).
The sustainability of a building depends on the decisions taken by the stakeholders in the
construction process: owners, managers, designers and firms, for example (Akadiri, 2011:3).
The pace of actions towards sustainable application depends on the awareness, knowledge
and understanding of the consequences of individual actions (Braganca et al., 2007:7;
Abidin, 2010). Among these is the environmentally responsible approach to the selection of
building materials (Anderson et al., 2009: 223). The material selection process is a complex
process influenced and determined by numerous preconditions, decisions and consideration
(Wastiels & Wouters, 2009: 379). The selection of building materials is one of several factors
that can impact the sustainability of a project (Nassar et al., 2003: 545). An appropriate
choice of materials for a design process plays an important role during the life cycle of a
building (Treloar et al., 2001:140; Zhou et al., 2009).
Resolving the housing delivery problem entails a holistic approach towards building houses
that are not only affordable but equally sustainable (available) to both the present and future
users. Hence there is a need to investigate the effects of cost of building materials on
housing delivery, which this research intends to achieve through the conceptual framework
represented in Figure 1.1, a conceptual framework presenting the effect of cost of building
materials, typical selection criteria, and typical factors responsible for the cost of building
materials, encapsulating the direct and functional relationship of these variables for
sustainable affordable housing delivery process.
The conceptual framework for this study is illustrated in Figure 1.1.
4
Sustainable Housing Delivery
Factors responsible for cost of building
materials
Cost of Building Materials
Selection Criteria
Fluctuation Stakeholders
satisfaction Government
Policy Currency
exchange Weather
conditions Inadequate
production of raw materials.
Resources efficiency – Materials, Manpower and Machinery.
Indoor air quality Energy efficiency Water Conservation Affordability Stakeholders’
satisfaction (Cost, time and quality)
Building materials
Functional relationship Functional relationship
Direct relationship
Direct relationship
Figure 1.1: Conceptual framework
1.3 Problem statement
The demand for housing of all types, coupled with inflation and monetary supply, poses
caused a significant challenge to the cost of building materials in the construction industry
(Eshofonie, 2008). The problem of high costs of building materials militate against effective
delivery of sustainable housing as building materials play such a necessary and substantial
role in the construction of housing.
Jagboro and Owoeye (2004:10) established that increase in the price of building materials
has multiple effects on housing development. Significant increase has brought about loss of
client confidence in consultants, as well as added asset risks, inability of developers to
deliver affordable housing and loss of investment in the construction industry. Therefore, an
improved sustainable housing delivery within budgeted time, cost and expected quality,
taking into consideration stakeholder satisfaction and cost of building materials is an
absolute necessity.
1.4 AIM AND OBJECTIVES OF THE RESEARCH
1.4.1 Aim
The aim of this research is to investigate the effects of building materials cost on the delivery
of sustainable housing.
5
1.4.2 Objectives
The objectives of this research are as follows:
1. to examine factors responsible for increase in cost of building materials that
ultimately hinder sustainable housing delivery;
2. to evaluate the effects of increase in the cost of building materials on the delivery of
affordable housing;
3. to ascertain the criteria to be considered in the selection of building materials for
sustainable affordable housing; and
4. to establish solutions to factors causing increase in the cost of building materials
towards sustainable affordable housing delivery.
1.5 Research questions
The research questions to be addressed are as follows:
1. What factors are responsible for increase in the cost of building materials?
2. What are the effects of high cost of building materials on affordable housing delivery?
3. What are the factors to be considered in the selection of building materials for
sustainable affordable housing delivery?
4. How could building materials enhance affordable sustainable housing delivery?
1.6 Significance of the study
This research will enable clients, contractors and consultants to take an economic approach
to housing delivery, such that they would be able to identify the predominant factors leading
to increases in the cost of building materials in the Western Cape. The application of the
solution to minimise cost of building materials will enhance client confidence in consultants,
reduce investment risks, and generally boost the viability and housing sustainability. Also,
this research will educate the general public on the implication of upward increase in the
cost of building materials on affordable housing delivery in Western Cape. The research
outcome ultimately will sensitize the South African government to the need to implement
policies for reducing the cost of building materials in the Western Cape and thereby
encouraging massive sustainable affordable housing delivery within the province.
6
1.7 Research methodology and design
When undertaking research it is important to choose the correct methodology to ensure that
research objectives are met and the findings are valid (Steele 2000:16; Fellows & Liu,
2003:21). A preliminary pilot study was conducted by administering questionnaires to
construction practitioners (target groups) to identify the factors and evaluate effects of
increase in the cost of building materials in the construction industry of the Western Cape of
South Africa. The pilot study focused on factors responsible for increase in the cost of
building materials, the effect of increase in cost of building materials on housing delivery,
and then criteria to be considered in the selection of sustainable building materials.
The pilot study aided in the formulation of the research questions and objectives for a
precise and modified questionnaire, one which would thoroughly investigate the interests of
this research.
1.7.1 Research design
Leedy and Ormrod (2010) specified that the research method and design adopted in a
research determines its uniqueness and eventually the success of the research. The nature
of a research topic, its aim and objectives and the resources available largely determine its
design (Creswell, 2003:6), as a research design can be qualitative, quantitative or a
combination of the two (Creswell et al., 2011). Thus, the mixed method research approach
combines quantitative and qualitative methods for data collection (Clark et al., 2008). The
research design adopted in this study focuses on the procedures, rules and guidelines in
line with the aim and objectives of the study. Therefore, the mixed method approach was
adopted for this study: a quantitative research approach with construction stakeholders was
validated using qualitative interviews with construction site supervisors.
7
Table 1.1 Relationship between research objectives, research questions and research methods
RESEARCH OBJECTIVES RESEARCH QUESTIONS RESEARCH METHODS
To examine factors responsible for increase in cost of building materials that ultimately hinders sustainable housing delivery
What are the factors responsible for increase in the cost of building materials?
Review of relevant literature and analysis of questionnaires and interviews
To evaluate the effects of increases in the cost of building materials on the delivery of affordable housing
What are the effects of cost of building materials on affordable housing delivery?
Review of relevant literature and analysis of questionnaires and interviews
To ascertain criteria to be considered in the selection of building material for sustainable affordable housing delivery
What are the factors to be considered in the selection of building material for sustainable affordable housing delivery?
Review of relevant literature and analysis of questionnaires and interviews
To establish solutions to the factors causing increases in cost of building material towards sustainable affordable housing delivery
How could building materials enhance the affordable sustainable housing delivery?
Review of relevant literature and analysis of questionnaires and interviews
1.7.2 Population of the study
The population of this study comprises construction stakeholders and site supervisors in the
Western Cape, South Africa.
1.7.3 Instrument for data collection
Primary and secondary data collection methods were adopted in the research study. The
primary data was collected using structured open-ended and close-ended questionnaires in
conformity with the research objectives. The secondary system of data collection for this
study involved an extensive review of relevant literature – primarily previous research –
which includes a review of published conference papers, textbooks, published article in
8
academic journals. In addition, qualitative interviews are used to validate the findings
obtained through the quantitative research.
1.7.4 Administration of instrument
The questionnaires were self-administered to obtain general information from the
respondents as well as more specific information sought to meet the objectives of this study.
1.7.5 Techniques of data analysis
Quantitative data were analysed using a generic software package known as the Statistical
Package for Social Science (SPSS version 24). The Likert scale is used to determine the
range of each respondents agreement or disagreement to statements by a ranking of 1-4.
Data gathered from questionnaires were analysed using descriptive statistics. Content
analysis was used to analyse the qualitative data gathered and each interview was
transcribed and checked for accuracy for respondent validation. A reliability test of the data
collected was assured by the Cronbach’s Alpha Co-efficiency test.
1.7.6 Scope and limitation of the study
Information was gathered from construction stakeholders and materials suppliers in the
Western Cape of South Africa. Respondents for this study include the various stakeholders
in the construction industry.
1.8 Key assumptions
This study assumes the following:
Selected construction companies face challenges with the high cost of building
materials on site.
Questionnaires were designed to ask relevant questions in regard to the research
objectives and research questions.
The research population provides relevant information to inform and justify the study
objectives and research questions.
9
1.9 Ethical considerations
All names of participants (organisations and individuals) remains anonymous on all research
documents, with respondent particulars guarded with extreme privacy. Research participants
(organisations and individuals) are not be paid or compensated any way whatsoever for
participation. The research quality is assured by validating quantitative data with the
conduction of qualitative interviews.
1.10 Thesis structure
The thesis will be structured as follows:
Chapter One: Introduction –This introductory chapter comprises the background of study,
statement of problem, research questions and objectives, methodology, limitations, key
concepts, significance of study and the chapter outline.
Chapter Two: Literature review – The literature review emphasises previous works of
various researchers related to this study of the construction industry, in textbooks, articles,
journals and dissertations affiliated with sustainable development, effects of cost of building
materials on housing delivery, factors responsible for increase in the cost of building
materials and criteria for selection of sustainable building materials.
Chapter Three: Methodology – This chapter presents the research method adopted in the
study towards achieving the research aim and objectives. Additionally, this chapter examines
the research design, research population, sampling technique, instrument for data collection,
administration of instrument, technique for data analysis and model formation.
Chapter Four: Analysis and discussion — This chapter provides information from the
elicited data, while also analysing the results obtained in the study, discussing the research
findings, and further representing results in both graphical and tabular formats.
Chapter Five: Summary, conclusion and recommendations – This chapter presents a
summary of findings, overall conclusions drawn and final recommendations made for further
study.
1.11 Research process
Figure 1.2 illustrates the process of the research from inception to completion.
10
RESEARCH
PROPOSAL
RESEARCH
QUESTIONS
RESEARCH
OBJECTIVESLITERATURE REVIEW
RRESEARCH METHODOLOGY
FORMATION
DEVELOPMENT OF
THEORITICAL RESEARCH
FRAMEWORK
DATA COLLECTION
(Collection of data and
capturing)
DATA PROCESSING AND
ANALYSIS
(Analysis of data and conclusion)
TO PROFER SOLUTIONS TO FACTORS CAUSING
INCREASE IN THE COST OF BUILDING MATERIALS
TOWARDS SUSTAINABLE HOUSNG DELIVERY
THESIS PRESENTATION
Figure 1.2: Research process
1.12 Chapter summary
This chapter provides an overview of this research. The background, research aim, research
objectives, research questions, significances, scope and limitations, literature review and
methodology of research were all briefly discussed. The subsequent chapters elaborate on
the literature review, research methodology, analysis and discussion of results, conclusions
and recommendations derived from the research.
11
CHAPTER TWO
2.0 LITERATURE REVIEW
2.1 Introduction
This chapter focuses on the review of relevant literature to establish the background of the
building industry, discussing the factors responsible for increases in the cost of building
materials and factors that commonly cause overrun costs in the construction industry. The
effects that increases in the cost of building materials have on the delivery of housing,
criteria to be considered in the selection of sustainable building materials for the delivery of a
sustainable housing in terms of cost, time and quality, and possible solutions to any
detrimental factors responsible for the increasing cost of building materials, will also be
discussed in this chapter.
2.2 Construction Industry
An appropriate, available and sustainable shelter is indispensable: a true basic need of all
human beings. Thus, housing options must constantly be available, affordable and certainly
durable in the built environment (Ihuah, 2015). The construction industry is one of the most
important industries underpinning the economic development of any nation (Ofori, 1999).
Uwakweh (2005) concurs that the construction sector makes undeniably important
contributions to the socio-economic expansion process in developing countries by
contributing meaningfully to the gross domestic product. The National Treasury of the
Republic of South Africa (2012) described the building construction industry as a broad
collection of industries and sectors adding value in the creation and maintenance of fixed
assets within the built environment. Notably, Windapo and Cattell (2013) observed that the
construction industry must operate as a single unit rather than as a complex cluster of
industries in which building materials sector is among them. The construction industry plays
a very essential role in all developed and developing countries. In Europe, for example, the
construction industry is the key industry on the entire continent, employing more than 7% of
all European workers (Proverbs, Holt & Olomolaye, 1999:198). In the US, the construction
sector contributes 14% to the gross national product and some 8% of total employment
(Thibolt, 2002:567). Similarly, the South Africa construction industry has a share of 5.8% of
the gross domestic product, employing approximately 7% of the South African workforce
(Statistics South Africa, 2012).
12
FIFA 2010 brought noteworthy changes to the South Africa construction industry (Windapo &
Cattell, 2012). The construction industry accounts for approximately 9% of the gross
domestic income (GDI), and the gross fixed capital formation (GFCF) contributes over 35%
to the country (CIDB, 2004a: online). Therefore, there has been a severe increase in the GDI
of the South African construction industry with over two hundred and sixty-eight million rand
(R268 million) between 2007 and 2011 (Solanke, 2015:22). This is evidence that the
construction industry is an active driver of the socio-economic development in South Africa
(Windapo & Cattell, 2013). Similarly, the building material industry contribution to the
economy of any nation cannot be overemphasized, as its output governs both the rate and
the quality of construction work (Akanni et al., 2014).
Conversely, the construction industry has inherent disadvantages as well: the construction
sector plays a significant role in unsustainable development and this could be attributed to
urbanisation, industrial activities, unruly use of natural resources and unplanned rapid
population growth (Son et al., 2011:337). By virtue of its size, construction industry is one of
the largest consumers of energy, material resources, and water, and also a formidable
polluter of the environment (Ding, 2008; Ding et al., 2010).
Materials such as stones, wood, straws, clay, lime, and brick occurred naturally as building
materials (Akanni, 2006:14; Taylor, 2013:100). Due to improvements in technology and
science at the beginning of the 20th century, materials with better performance and durability
were introduced, for example, reinforced concrete, steel, plastic and metal (Taylor,
2013:101). The process of housing development must be based on principles of
sustainability, which should be applied throughout the process from conception, construction
and final use of the buildings (Adedeji, 2012). The enormous percentage of building
materials that make up to the total cost of construction project costs make it an essential
component with a massive effect on the cost of construction and basically the affordability
(or lack of) of proposed construction projects (Windapo & Cattell, 2012). However, this could
be exacerbated to the significant loss of performance capacity encountered within the South
African construction sector. Windapo and Cattell (2013) explored thirteen critical factors that
influence the performance, growth and development of the South African construction
industry; the top critical challenge facing the construction industry was increase in the cost of
building materials. Clearly, then, is it imperative to find solutions to this factor, and others,
resulting in increase in building materials cost.
13
2.2.1 Construction stakeholders
Takim (2009) described construction stakeholders “as a group of people who have the ability
to influence production process and final products of a construction project, whose quality of
living and environmental statues are affected by positively or negatively by the project”.
Similarly, Isa, Alisa and Samad (2014) noted that construction project stakeholders are a
group of intellectuals incorporated in the scheduling/development phase of a building project
to achieve cross-functional construction responsibilities. Takim (2009:169) and Yudelson
(2010:41) added that for effective management of any construction project, an integrated
project team is comprised of a wide range of professionals such as users (owners), general
contractors, architects, project managers, consultants, engineers and government
agents/commissioning authorities depending on the complexity of the project. Pheng and
Chuan (2006:31) explained that the ability of construction team to effectively communicate
and maintain a sharp and professional working environment is termed the ‘team
relationship’. Construction activities on a project site will be accomplished through effective
team work. Therefore, effective team work enhances adequate use of budgeted cost during
production process (Cohn & Ralston, 2005).
Notably, the importance of stakeholders in any construction project is relative to attaining
success and sustainability during construction (Takim, 2009:167; Menassa & Baer, 2014).
According to Isa et al. (2014:42), making crucial decisions on sustainability implementation is
the ultimate role of construction stakeholders in constructing housing that meet the
demanding needs of the present generation without conceding the satisfaction of the future
generation. One of the critical stages in building construction projects for sustainability
integration is the planning process. Therefore, to attain an effective sustainable housing
project, it is important for stakeholders to act together throughout the planning processes of
the project (Isa et al., 2014). In addition, Storvang and Clake (2014) further explained that
the planning process provides a platform for stakeholder participation to add relevant
perception to the construction process in a project.
The four (4) main construction project stakeholders who are accountable for sustainability
performance and ultimately, the accomplishment of the project, irrespective of the nature
and scope of the project in both developing and developed countries (Azmy 2012; Bal,
Bryde, Fearon & Ochieng, 2013; Wang & Huang, 2006), are as follows:
project owners;
construction contractors;
14
project managers; and
government stakeholders.
Project owners, either in form of public or private entities – such as developers, clients or
project land owners – carry the responsibility of securing construction contractors and
consultants with qualified skill on sustainable building production so that they can estimate
the worth of their investment and purchases (Solanke, 2015). Additionally, clients should be
certain that sufficient financial requirements are ready prior to the commencement of any
project (Eshofonie, 2008), as cost is one of the major, among numerous factors, with which
consultants must grapple. The construction contractors and consultants include engineers,
architects, quantity surveyor, materials suppliers who are principally in charge of producing
construction documents and physically representing design documents either through
subcontract or sub-subcontracted labour (Robichaud & Anantatmula, 2011). However,
Solanke (2015) explained that ability to recognize the responsibility and influence of the
stakeholder involvement in a project is one of the major qualities of a successful project
manager. Also, the project manager should ensure that project owners are cognisant of the
process of construction, the challenges and the strategies before and during project
construction.
Government agencies undertake the role as overseers of building regulatory policies and
codes that encourage the scope and objectives of sustainable building practices. The
participation of local government as stakeholders in the planning phase will safeguard the
project design plans in accordance with regulations (Perkins et al., 2011)
2.3 Sustainable development and sustainable housing
Sustainability is “the ability to meet the present needs of humans without compromising the
ability of the future generations meeting their own needs” (Du Plessis, 2007). ‘Meeting the
needs of the present’ refers to the development aspects of sustainability, including economic
issues (Ebsen & Ramboll, 2000). Therefore, sustainability should be the main principle
undergirding housing design and one of the important dimensions of housing quality
(Morgan and Talbot, 2001:321).
Thus, for development to be sustainable, it must take into account social and ecological
factors, as well as economic ones, of the living and non-living resource base on long-term as
well as the short-term advantages and disadvantages of alternative actions (Akadiri, 2011).
Diesendorf (2000:34) defines sustainability as the goal of ‘sustainable development’ or
‘economically sustainable and socially just development’ which enhance the natural
15
environment and human well-being. Gibberd (2005:1606) views sustainability as a
multifaceted interaction between ‘environment, society and economy’, and further pinpointed
that these characteristics (environment, society and economy) are generally accepted as the
prime contributors to sustainability. The idea of sustainability involves enhancing the quality
of life, thereby empowering people to live in a healthy environment, with improved social,
economic and environmental conditions (Ortiz, Castells & Sonnemann, 2009). However,
Beder (1996:100), Berggren (1999:432), Stigon (1999:426) and Rohracher (2001) discussed
the concept of sustainable development in the context of considering economic growth in
addition to the social and environmental dimensions. Economic growth, with emphasis on
aspects such as financial stability and material welfare creation, is the ultimate goal for every
government to secure rising standards of living and increase the capacity of goods and
services provisions to satisfy human needs. In spite of differing perceptions about the
precise meaning and possible interpretation of the term sustainable development, it is widely
accepted that for a development to be sustainable it must examine ecological, economic,
social and ethical aspects of reality, as illustrated in Figure 2.1.
Growth Efficiency Stability
ECONOMIC
Intra-generational equity
Basic needs / livelihoods
Valuation / internalisation
Incidences of im
pact
Poverty
Equity
Sustainability
Climate change
SOCIAL ENVIRONMENTAL
Empowerment
Inclusion / consultation
Resilience / biodiversity
Natural resources Pollution
Fig 2.1: Sustainable development triangle
(Source: adapted from Munasinghe, 1994)
Figure 2.1 illustrates the relationship between humans, their environment, economy, society
and technology, concepts which are well-supported in literature by many other researchers
(Du Plessis, 2007:67; Bakhtiar, Shen & Misnan, 2008:56; Son et al., 2011. Hill and Bowen
16
(1997), in Figure 2.1, highlighted the acceptability and relevance of each pillar to any
construction project, placing emphasis on the importance of combining economics and
ecological development planning (Akadiri, 2011:48). In order to attain sustainability in
building construction, adoption of life-cycle assessment (LCA) as a standard of evaluation
affords an improved quality of living for the inhabitants (Vatalis et al., 2013). However, the
sustainability level of a building, measurable using a Life Cycle Assessment tool (LCA),
depends on the quality of materials used in construction and/or maintenance. Walker-
Morison et al. (2007) further stated that sustainability in building production is efficiently
measured when the accessible materials are utilized efficiently to decrease material wastes,
environmental pollution and construction cost.
Sustainable housing means “housing which contributes to community building, to social
justice and to economic viability at a local level (Morgan & Talbot, 2001:321). Thus,
sustainable housing should meet a certain number of objectives in term of resource and
energy efficiency, CO2 and GHG (greenhouse gas) emissions reduction, as well as pollution
prevention, mitigation of noise, improved indoor air quality and harmonization with the
environment (John, Clement & Jeronimidis, 2005:139). Ideally, housing should be less
expensive to build, last forever with modest maintenance, and be able to return completely
to the earth when abandoned (Bainbridge, 2004:55). So, reach this ideal and develop truly
sustainable housing, housing initiatives must be socially acceptable, economically viable,
environmentally friendly and technically feasible (Choguill, 1999).
2.4 Building materials
Building materials play a vital role in the construction industry as they are those materials put
together in erecting buildings; construction project is not feasible without the inclusion of
building materials (Akanni et al., 2014). Akanni et al. (2014) explained that building materials
remain the most substantial input in project development and, because of this, play an
undeniably significant role in the delivery of construction projects. According to Adedeji
(2012), about 60% of total housing expenditure is spent on building materials. Notably,
Karana, Hekkert and Kandachar (2010) indicated that appropriate use of the building
materials, in respect of the expertise involved in the building construction process,
determines the strength, functionality and quality of the building. Building materials play a
crucial role in enhancing sustainability of buildings and contributing to economic wealth of
the nation (Akadiri 2011:100). However, Donyavi and Flanagan (2011) observed that in
order to reduce construction costs, and to improve productivity, quality and timely project
delivery, material management effectiveness must be a main concern. The importance of
building materials in sustainable housing delivery cannot be underestimated.
17
2.4.1 Factors responsible for increase in the cost of building materials
As discussed, the cost of building materials has presented a formidable challenge to the
construction industry (Akanni et al., 2014:1). Windapo and Cattell (2013:73) are in
agreement, contending that the preeminent challenge affecting the performance of the
construction industry and projects in South Africa is primarily the increasing cost of building
materials. Hence, volatility tends to push the cost of building materials up and transfers a
major risk to all parties involved: suppliers, contractors and clients (Li, 2001:689). Ughamadu
(1993:30) also asserted that local currency devaluation was a factor surging the cost of
building materials up.
Jagboro and Owoeye (2004:9); Mojekwu, Idowu, and Sode (2013:360); and Idoro and
Jolaiya (2010:103 ), in their respective studies, pointed out many factors – such as the
change in government policies and legislations, scarcity of raw building materials, fluctuation
in the cost of fuel and power supplies, inadequate infrastructural facilities, unfortunate
corruption, fluctuation in the cost of plant and labour, and seasonal changes – as being
factors responsible for the escalating cost of building materials. Other factors responsible for
the increase cost of building materials identified by researchers are these: fluctuation in the
cost of transportation and distribution, political interference, local taxes and charges,
fluctuation of cost of raw materials, cost of finance, inflation, and fluctuation in the exchange
rate. Moreover, Oladipo and Oni (2012) analysed some macro-economic indicators
impacting the cost of building materials, which include the following: exchange rate of local
currency to other currencies globally, inflation rate and interest rate charge on loans.
Factors responsible for increase in the cost of building materials fall into four categories:
economic related factors; building production related factors; external factors; and
stakeholder related factors.
2.4.1.1 Economic related factors
2.4.1.1.1 Exchange rates
The exchange rate is the amount for which one currency is exchanged for another currency,
used in determining the strength of one currency against another (Windapo & Cattel,
2012:192). South Africa produces its own strategic materials and yet relies on imported
equipment. Therefore, increases in materials cost within the industry are a cause for concern
(Windapo & Cattell, 2013:70). However, about 50% of all building materials and components
incorporated into construction, or parts of the material ingredients required for the
manufacture of the construction products, are sourced from overseas (Udeh, 1991). The
18
ratio to which building material costs are affected by exchange rates depends on the type
and quantity of material being imported by a country at a specific time, the need to import the
raw materials used in the production of building materials locally, and on whether or not local
materials (such as copper, timber and steel) are internationally traded commodities
(Windapo & Cattell, 2012:192). Oladapo and Oni (2012:132) opined that the introduction of
the foreign exchange market has had a detrimental impact of the prices of building materials.
2.4.1.1.2 Inflation
According to Adamu (2013), inflation is an upsurge in general price level in any economy. It
is primarily the measure of how the price of goods and services increase over time (Fichtner,
2011). Clearly, any other factor that delays a project will further expose the project to the
risk of inflationary cost increases. However, Windapo and Cattell (2012:191) explained that
there is a time interval between increase in inflation before resulting in actual increase in the
cost of building materials. Due to the nature of the process and the rate of return for work
undertaken on construction projects, the effects of inflation can mean loss of profit to
contractors and higher cost overrun to project owners (Nega, 2008:57).
2.4.1.1.3 Interest rate
The high interest rate of banks and the unpredictability in the foreign exchange market result
in serious depletion of a nation’s foreign exchange resources, harshly affecting the industry
with import dependence of about 60% of its raw materials (Jagboro & Owoeye, 2004:10).
However, Oladapo (1992:16) opined that across the nation, many construction and profitable
real estate projects and housing have either been put on hold or abandoned half way
because of the scarcity of capital or because of the sky rocketing cost of borrowing.
2.4.1.1.4 Fluctuation in the cost of building materials
The studies of Rahman et al. (2013:518) revealed that fluctuation in cost of building
materials was ranked as a significant factor of cost overrun. Frimpong et al. (2003) revealed
price fluctuation as the most severe cause of project cost escalation. Zewdu et al. (2015)
conducted a study to identify the factors causing cost overrun in Ethiopia, finding revealed
that the main cause of cost overrun was fluctuations in cost of building materials, a
fluctuation attributable to the limitation in exchange rate which in turn affects building
material cost and the general cost level.
19
2.4.1.1.5 Inadequate production of raw material
Ogunlana, Krit and Vithool (1996:38) postulated that the reason for shortage of materials
could be the ineffective supply of materials occasioned by general shortages in the industry,
poor communication amidst sites and head office, poor purchasing planning and poor
material coordination. Shortages of some construction materials may arise where the level of
development activity is unusually high. If this had not been anticipated and integrated into
the original cost estimate, the prices of these materials will increase (EU Framework
1998:13). Ensuring a timely flow of materials is an imperative responsibility of material
management, as unavailability of material will likely result in delays and extra expenses
(Rajaprabha et al., 2016:1).
2.4.1.1.6 Supply and demand of building materials
Supply and demand of materials will determines the price of building materials (Oladipo &
Oni, 2012:132). Windapo and Cattell (2012:191) stated that the demand for more housing
and delay in supplying the building materials (or lack of materials), will add to the trends in
the price of building materials, where the law of supply and demand can be related. Windapo
and Cattell (2012:192) admitted that building materials cost increases are dependent on the
market conditions under which they are manufactured. For example, the researchers noted
that material cost will increases if only one or two companies are manufacturing building
materials, as compared to those for which many manufacturers compete for the same
market. A precondition for cost-effective construction is the availability of construction
materials at the required time and location on site (Mohan et al., 2002:627). Delay in the
supply of materials on site is one causative factor of cost overruns in construction projects,
particularly in developing countries.
2.4.1.2 Building production related factors
2.4.1.2.1 Site related factors
Construction waste becomes a universal concern faced by construction stakeholders. Waste
generated during construction activities on site can affect delivery of a construction project
significantly, specifically on construction cost, construction time, productivity and
sustainability aspects (Nagapan et al., 2012). According to Nagapan et al. (2012), the
majority of waste generated during construction is materials waste, primarily as a result of
the use of un-reusable materials, leftovers and debris. Unfortunately, this material waste
amounts about 9% of the weight of materials purchased (Azis et al., 2012:630). Material
mismanagement during construction can lead to an increase in costs of construction,
20
whereas effective management of materials can bring extensive savings to project costs
(Rajaprabha et al., 2016:1).
Increase in material cost is primarily due to increase in transport charges (Windapo & Cattell,
2012:191). For example, Eshofonie (2008:19) noted that an increase in the cost of fuel will
result in drastic increases in transportation costs. Hence, manufacturers raise the cost of
building materials to cover the fuel increase when distributing the finished products from
factory to suppliers and end-users.
2.4.1.2.2 Human factors
There are three typical resources associated with construction: material, machinery and
manpower (3Ms). Manpower is the source of more threats than construction materials and
machinery (Hanna et al., 2005:734). In the study of Windapo and Cattell (2012:197), as they
sought to benchmark respondents’ perceptions against actual factors that may affect future
building material prices in South Africa, it was revealed that labour cost had the highest
correlation with building material prices, followed by transport cost. Notably, poor
communication between management and labour can reduce morale of the labourers,
further decreasing production while increasing project cost (Eshofonie, 2008:17). Mustapha
and Rashid (2012:7) pointed out effective communication management as a key factor for
improving the management of human resources in construction.
Many studies have been undertaken to explore the factors affecting construction labour
efficiency. Previous studies undertaken by Kaming et al. (1997:26); Zakeri et al. (1996);
Makulsawatudom et al. (2004:3); Eshassi et al. (2009:252); Ameh and Osegbo (2011); and
Rivas et al. (2011:316) determined that shortages or unavailability of building materials on
site is one detrimental factor affecting labour productivity and thereby increasing cost of
construction over budgeted costs. Empirical evidence comes from a study conducted by
Adebowale (2015:116): findings revealed delay and insufficient wages of construction labour
as two of the top five labour-related factors affecting the efficiency of construction labour,
leading to rework, reduced speed of work and poor overall construction performance (Ameh
& Osegbo, 2011; Soham & Rajiv 2013; Durdyev et al., 2012).
2.4.1.2.3 Design related factors
A construction project performance is inevitably impacted by design changes (Olawale &
Sun, 2010). Design change is a kind of change that impacts the method of work as was
originally planned budgeted or scheduled (Abdul-Rahman et al. 2015). However, it was
further revealed by researchers that changes do frequently arise at any stage of a project
due to a variety of reasons stemming from diverse sources – with significant impact. Zakeri
21
et al. (1996); Makulsawatudom et al. (2004); Enshassi et al. (2009); Dai et al. (2009); Ameh
and Osegbo (2011); Jarkas and Bitar (2012); and Soham and Rajiv (2013) stated that the
non- challenge attitude of design professionals to drawing queries (clarity, complexity and
drawing errors) and inadequacies of information for production mean design challenges on
construction projects. Oyedele and Tham (2006:2091) affirmed that there must be excellent
communication between design team members, including simplicity, certainty, briefness and
completeness of the design. Similarly, team-related matters such as team building,
teamwork, team organization and team experience are frequently acknowledged as
essential factors for project performance (Sanvido et al., 1992:100). Hence, lack of
significant consideration for these matters in the design phase may extend the project
duration leading to cost overruns (Oyedele & Tham, 2006:2091).
Design change is connected to additional work, due to the absence of comprehensive
briefing on the economic, functional and technical requirements of the project by the clients
(Mansfield et al., 1994). Abdul-Rahman et al. (2015) emphasized that design change orders
resulting in additional work can account for as much as 50% of project cost overrun – quite
substantial! Furthermore, additional work is a significant factor contributing to cost increases
and schedule delays in construction projects. Wrong methods of estimation can be ascribed
to lack of satisfactory experience of quantity surveyors (Mansfield et al., 1994). Arguably, all
these factors impinge significantly on the cost of materials.
2.4.1.3 Stakeholder related factors
2.4.1.3.1 Supplier default
Manavazhi and Adhikari (2002:630) found the factors responsible for supplier default come
from the fact that some suppliers control a monopoly of the market by keeping the price high
and restricting the output, showing little or no awareness of the needs of the customers. The
researchers stressed that because of the high demand of some building materials, some
suppliers wait for a high accumulation of orders, thereby generating problems associated
with importing raw materials as well as increased exchange rates. The results of the study of
Elinwa and Silas (1993:711) revealed that fraudulent practices and kickbacks was the
second significant factor responsible for an increase in construction cost as perceived by
construction professionals interviewed
2.4.1.3.2 Improper planning
Improper planning is one of the most important factors affecting the cost of building
materials. Contractors should utilize all resources in effective ways. Proper scheduling is
essential in project resource utilization, as the reverse, inadequate planning, will increase the
22
project cost (Eshofonie, 2008:15), suggesting that where there is no effective contractor
scheduling and planning on site, these factors will be responsible for construction project
delays (Assaf & Al-Hejji, 2006:351).
2.4.1.3.3 Delay in the supply of building materials
Timely delivery of building materials is essential. To this end, Ramanathan et al. (2012)
revealed that quite a number of projects during building production processes experienced
extensive delays in the supply of building materials, thereby exceeding the initial budgeted
cost. Unavailability of building materials at the required time on site during construction
frequently results in production materials deterioration and wastages, time wastage, low
labour productivity and production cost overruns (Solanke, 2015). However, an effective
material management system is significant during construction and for this, identification of
materials should be made prior to the time of using the materials. This is an important step in
avoiding late delivery of materials (Rahman et al., 2012).
2.4.1.3.4 Client contribution to design change
While a change in a project’s design can arise for any number of reasons, Ogunlana,
Promkuntong and Jearkjirm (1996) acknowledged that clients are actually the major cause of
change for many reasons: it could be for marketing purposes or due to an economic
situation to meet customer demands. Also, adjustment or change might occur as a result of
newly-emerging concepts perceived by the client for the project to achieve anticipated
functional requirements. Alsuliman et al. (2012) further confirmed that clients initiate most of
changes in building design which are likely to extend the delivery of projects at construction
costs higher than budgeted cost. Arguably, changes ordered by clients will bear a
consequence on the period of construction activities and increase the construction materials
cost. A number of other studies have also shown that design changes are primarily caused
by clients (Love, Frani, & Edwards, 2002; Memon et al., 2014; Hamzah et al., 2012).
2.4.1.4 External factors
2.4.1.4.1 Force majeure
Force majeure, otherwise known as ‘Acts of God’, is a term that covers a range of events,
including revolution, war, riot, earthquake, landslide, fire, political and economic instability
and other such risks (Nega 2008:53). Where it occurs, it will result in significant increase in
the cost of building materials.
23
2.4.1.4.2 Weather conditions
While building materials are a significant component of any building project, climate change
directly or indirectly will also have an effect on the use of building materials before or during
building construction. Climate changes contribute a vast challenge to global warming
emission of CO2 by buildings under construction and in use (Windapo & Cattell, 2013:70). As
actual site conditions for a construction project are not usually determined until construction
begins, some changes may occur due to hostile weather conditions or changes in sub-soil
conditions (EU Framework, 1998). Hence, unanticipated changes in sub-surface and surface
ground conditions can sometimes involve major changes in the design of a project at great
expense; potentially further increasing costs of constructional materials and adding to
construction project delay. For example, a study by Rajaprabha et al. (2016) revealed that
heavy rainfall has an effect on the concreting works for structures, which no doubt will then
require extra materials and time.
2.4.1.4.3 Government policies
Windapo and Cattell (2013:70) noted that the South African Government has passed more
than 1,000 pieces of legislation since 1994, which in turn procreated several regulations,
giving the impression of over-regulation. According to Mansfield, Ugwu, and Doran
(1994:255) and Obadan (2001:15), the building materials sector is one that government
policies established. In the findings of Dlakwa and Culpin (1990: 238) and Adekoya
(2003:29), one of the factors affecting the cost of building materials in the Nigeria
construction industry was identified as government fiscal policies. According to Mansfield et
al. (1994: 255), governments may also invoke their powers to initiate or halt projects on
political, social and environmental grounds. Thomas and Martin (2004) stressed that no
construction work happens in a single space; rather it is subject to a group of powers from
regulatory control to political intervention. Among other external factors responsible for
increase in cost of building materials is the lack of proxy substitutes for some building
materials.
2.5 Construction project consideration
Cost, quality and time are the three major factors significantly essential in any construction
project (Lambropoulos, 2005:452). Nonetheless, the primary goal of the construction project
manager is accomplishing successful completion of the construction project within the
predefined time, budgeted cost and expected quality checks (Lambropoulos, 2005:452).
Kerzner (2013) emphasized that the process of project management is labelled successful
when the project objectives are achieved within time, cost and desired technological level.
24
Consequently, the management of construction projects entails an in-depth knowledge and
understanding of present management techniques, designs and construction processes
(Koskela & Howell, 2001). For effective sustainable project management, the project
managers require credible skills involving controlling, organising, planning, forecasting and
co-ordinating (PMBOK, 2008; Kerzner, 2013). Hence, effective project management is
achievable by the application of several management techniques during construction
(PMBOK, 2008:67). Figure 2.2 illustrates the application of project managerial processes in
construction project.
Figure 2.2: Managerial processes in construction project management
(Adapted from Koskela & Howell, 2001:186)
2.5.1 Cost consideration
Cost consideration is a major key throughout project management life cycle, regarded as
one of the most important parameters of a project and the driving force of project success
(Memon et al., 2010:42). However, Chitkara (2006:106) delineated the elements of cost to
include labour costs, material costs, plant and machinery costs and other, often unidentified,
expenses. These, for ease of estimation, are grouped into direct and indirect costs. Direct
costs are the costs ascribed to the construction workforce carrying out a job with the use of
specific materials and equipment. On the other hand, the costs ascribed to overhead, profit
and bond are known as indirect costs (Knutson et al., 2009:149). According to Chitkara
(2006) direct costs fluctuate from about 65% to 93% of the total costs. Hence, Achuenu and
Ujene (2006:99) posited that the average proportions of material costs in the components
investigated vary between 42%-77% in public and private projects, while the average
proportion of labour costs vary between 23% and 58% in public and private projects in some
selected states in Nigeria. Thus, in construction projects, the cost of materials and plant
25
components represent approximately 70% of the project sum in civil engineering projects,
while material cost represents 45%-50% in housing and commercial building projects
(Donyavi & Flanagan, 2009:12).
The primary factors affecting project costs are qualitative, such as client priority on
construction time, contractor planning capability, procurement methods and market
conditions, including the level of construction activity (Elchaig et al., 2005:534). Similarly,
Chan and Park (2005:295) are of the opinion that cost is affected by a number of factors
precisely because the construction industry is multidisciplinary and its work integrates many
stakeholders. For that reason, the consequences of poor cost anticipation and ineffective
management are cost overrun, delay and abandonment of project, loss of profit, bankruptcy
and insolvency by contractors. Oyewobi et al. (2011: 147) and Ogunsemi and Aje (2006:34)
found other consequential losses are loss of quality, client dissatisfaction and disputes
among stakeholders.
Cost overrun appears to be a common occurrence, accompanying virtually all projects in the
construction industry (Azhar et al., 2008:500). Moreover, Kasimu (2012:775) contended that
cost overrun problem is more rampant than time overrun. Flyvbjjerg, Holm and Buhl
(2002:281) conducted comprehensive research on cost overrun in the construction industry
globally, finding that an exorbitant 9 out of 10 projects had overrun: overruns of 50-100%
were common! And overruns have been a constant problem for the 70 years of data
available. To buttress this, Aziz et al. (2013:2621) investigated 258 projects in 20 nations
with an approximate worth of US $90 billion (project size ranging from $1.5 million to $8.5
billion) and discovered cost overrun was usual, again happening in almost 9 out of 10
projects, with a medium of 28% higher than forecast costs. It was concluded that average
cost escalation in Europe was 25.7%, North America 23.6% and other geographical areas
was 64.6%, with cost performance in construction projects showing no improvement over
time. In fact, today it is in the same shocking order of magnitude as it was 70 years ago.
2.5.2 Quality consideration
Harris and McCaffer (2013) described the quality of a product or service to be characteristic
value added by the project manager to meet the listed requirements of a customer. Rumane
(2011:8) argued that construction quality not only encompasses the quality of materials used
in construction works, but also incorporates the complete management approach engaged to
complete a construction project, to ensure that the needs of the future generation are
sustained with the available resources not being compromised. In the context of sustainable
building delivery, quality management consideration remains a fundamentally prerequisite
26
for the production of buildings that satisfy client forecasts while reducing contingent recurring
cost related to operation and maintenance (PMBOK, 2008:190).
In an effort to encourage quality of production in engineering, the International Organisation
for Standards (ISO), founded in 1947 in Switzerland, was advocated and certified for
management standardisation. This body has been accepted internationally for quality
production legislation (Terlaak & King, 2006). It was also accepted internationally for
adoption of Total Quality Management (TQM); Six Sigma; Failure Mode & Effect Analysis
(FMEA) and Quality Inspection and Management (QIM) as approaches for quality building
production. Furthermore, ISO combines implementation of policies, attitudes, procedures,
technology, record keeping and resource management to achieve an acceptable minimum
quality of production (Knutson et al., 2009:506).
2.5.3 Time consideration
In the construction industry, one of the main objectives of consultants is to accomplish timely
completion of projects within specified budget and at prerequisite quality (Memon et al.,
2011:54). Chan and Chan (2004:211) defined construction time as the complete time
planned for a particular project, from the beginning of construction activities on site to
completion of the construction project. Choudhury and Rajan (2003) stated that when
determining the duration of a construction project, the size of construction team, method of
construction and equipment adopted to execute a construction project should be taken into
consideration for timely completion. Therefore, an effective use of time to utilize construction
resources effectively with reduced materials wastage and costs aimed at stakeholder
satisfaction is essential (Fapohunda & Omoniyi, 2011). Notably, stakeholder satisfaction and
timely project completion has been a yardstick for measuring project success in relation to
time, quality, scope and cost (Mallak, Patzak & Kurstedt, 1991; Takim, 2009; Pinder,
Schmidt, & Saker, 2013). A construction project is considered ‘commendably and
sustainably realized’ when the project is delivered on time, within cost and scope, and meets
the required quality. Hence, satisfying customer expectations of time, cost, quality and scope
are expedient. Figure 2.3 presents a model for continuous improvement in construction
productivity to enhance timely delivery of construction projects, at budgeted costs and at the
expected quality standards.
27
SystemQuality Management
Time ManagementControl
BenchmarkingLean construction
Planning, analysis and production
Management process
Introduce improvement in workers efficiency
Performance monitoringPerformance level
Work studyKey performance indicators
Improved productivityEarlier finish
Improved health and safetyLess construction wasteSustainable construction
Lower costImproved quality
Higher salaryImproved industry integrity
Fee
db
ack
Figure 2.3: Model for continuous improvement of construction productivity
(Adapted from Harris & McCaffer, 2013:47)
2.5.4 Human management
Human resources play a significant role in construction activities (Rahman et al., 2012). In
fact, the importance human resources cannot be underestimated in the construction
industry. Adequate application of construction materials and machinery is reliant on the
effectiveness of manpower in the construction industry (Adebowale, 2014:18). However,
28
Rahman et al. (2012) indicated that effective human resource management in the
construction industry will enhance productivity, reduce labour cost and maximise the profit of
the construction industry. Notably, the cost-effectiveness of construction projects is
dependent on the ability of supervisors to communicate effectively with workers, competently
direct activities of subordinates and proper planning of construction activities (Olabosipo et
al., 2011:255). Adebowale (2014:19) further emphasised that excellent communication
management is a main tool for improving the management of human resources in
construction for enhancing the production process and delivery of project within budgeted
cost.
2.6 Material management
Material management is a system of minimising waste on site, purchasing, delivering and
sourcing materials with the intent of ensuring that essential requirements are met (Kasim
2011:32). Similarly, the process of material management is characterized for planning,
handling and controlling all features needed to ensure that materials are available at point of
use, when needed, and at sufficient quality and quantity (Rajaprabha et al., 2016:1). To be
succinct, the aim of material management is to ensure that construction materials are
available at their point of use when needed (Patal & Vyas, 2011:1), as essential
management of materials improves productivity in construction projects. Hence, the effective
use and management of materials avoids delay in projects and optimizes a company’s cost
profitability (Rahaman & Alidrisyi, 1994:412). Hence, efficient materials management is a
critical component in project management. According to Dey (2001:394), material costs
constitute almost 60% of the capital of any housing industrial organization. However, early
purchasing of materials not only ties capital down but also increases accumulated interest
rate charges, with materials prone to deteriorate or be stolen during storage (Patel &Vyas,
2011:1). Therefore, ensuring a timely flow of materials is an important concern of material
management; effective sustainable use of materials must be serious concern to project
managers, as illustrated in Figure 2.4.
29
Vendor selection from the approval
list of vendors from the client
Material generated from site
Material ordered in the store
Indent is generated
Check availability in the store
Check for the balance item
Material inspection from
received stock
Rejection of the unacceptable
stock
Issue of material to the
concerned department
Figure 2.4: Process of material management [material flow chat]
(Adapted from Patel & Vyas, 2011:2)
To better understand material management for stakeholders, the following steps are
fundamental required for effective material management during construction, as proposed by
Patel and Vyas (2011:1).
broad knowledge of material estimation, budgeting and programming;
expansive knowledge in material scheduling, purchasing and procurement;
skilful stocks control procedures and technique;
good inventory control (purchase costs control, order costs and holding cost); and
30
material utilization and waste management.
Effective material management will produce the expected outcome, with the right quantities
of the right material at the right time (Arnold, 2004). Nevertheless, the expected outcome can
still be compromised by different management problems identified amongst contractors,
problems which vary in nature and impact but are usually related to inefficient management
of construction resources, including materials, labour, plant and subcontractors (Chan,
2002:59). Kasim (2011:32) highlighted these problems as follows:
late site storage facilities;
improper material handling;
poor general material logistics;
poor site access points;
operation limitations due to security consideration;
poor material procurement strategy; and
improper material deliveries.
Any small improper handling and managing of materials will have a massive impact on the
total project cost, time and quality. Donyavi and Flanagan (2011:465) noted that in order to
reduce construction cost, and thereby increase construction productivity, quality and timely
project delivery, and efficient material management must be a top priority. Efficient or
effective management of building materials has been identified as the easiest approach for
project managers to incorporate sustainable principles into a building construction project
(Akadiri & Olomolaiye, 2012:666).
2.6.1 Materials utilisation and wastage
Materials utilisation is an essential aspect of building construction which improves the
attainment of sustainable structures. Yehia et al. (2015) revealed that current statistics
indicate a high demand for construction materials: but increasing demand is accompanied by
an increase of construction waste. Baloi (2003) stressed that the rate of material usage in
construction has escalated shockingly due to its hostile influence on the environment.
Because of this, Lu and Tam (2013) emphasized that material usage in construction requires
a change in approach from a direct to a cyclic approach to achieve required sustainability.
According to USGBC (2008) strategies for material utilisation, emphasis is on the 4 Rs of
sustainable construction: reducing material consumption, and the use of renewable,
reusable and recyclable materials to minimise the harmful effects of construction on the
31
environment. Similarly, Yehia et al. (2015) stated that recycling has the ability to decrease
the quantity of waste materials chucked into landfills and to protect natural resources.
Therefore, the concept of the 4Rs approach is a dynamic law for an effective framework for
material utilisation and construction waste control.
2.6.2 Waste management
Kareem and Pandey (2013:345) described waste management as a means of “eliminating
waste wherever possible; minimising waste wherever feasible; and reusing materials which
could become waste”. However, all over the world, including South Africa, construction
activities contribute a considerable amount of waste generating a sizeable challenge faced
by the construction industry (Kasim, 2011). Correspondingly, Gulghane et al. (2015:62)
stressed that material waste has been acknowledged to have an effect on the productivity of
the industry and environmental impact on construction projects: this is a major problem in
the construction industry.
Construction wastes can be defined as materials or elements accumulated as a result of
demolitions or renovations; unintended material utilisation; abandoned, processed or
unprocessed surplus materials (Hong Kong Environmental Protection Department, 2010;
Nagapan et al., 2011). Construction waste arises from different construction activities taking
place on site, such as waste from land excavation, civil and building construction materials,
site clearance waste, roadwork waste and building renovation waste. This could be in form
of building debris from demolition process, rubble, earth material, concrete waste, steel
waste, timber waste, and mixed site clearance construction materials (Gulghane et al.,
2015:62).
Waste in construction could also be described as any ineffectiveness that results in the use
of equipment, materials, labour or capital in larger quantities (Napagan et al., 2012:23).
Therefore, waste in construction is not only concerned about the amount of waste of
materials on site, but also connected to numerous undertakings such as overproduction,
waiting time, material handling, processing, inventories and movement of workers (Alarcon,
1994; Formoso et al. 1999). Previous studies undertaken by Nagapan et al. (2012)
highlighted 81 factors causing construction waste, clustered into seven groups of factors:
design of project, handling of construction materials and equipment, construction workers,
project management, site condition, procurement of materials and external factors.
Construction waste can be minimised by implementing a waste management system for the
project. Then, the project activities are planned at every stage by every construction
personnel involved, in minimising the overall project waste generation (Thomas et al., 2013).
32
Waste management remains essential in the attempt to achieve sustainability. In addition,
the application of the 4Rs – reduce, reuse, recycle, and recovery – to the whole life cycle of
production, can lessen the wastage of building materials (Kareem et al., 2013; Thomas et
al., 2013; Bagdi et al., 2013). Efficient management of construction waste is a vital concern
in project management adding to the attainment of sustainable developments and
sustainable building delivery.
2.6.3 Cost overrun in construction project
Cost overrun is a major problem particularly in developing countries, where the cost overrun
sometimes exceeds the estimated cost of the project (Reina & Angelo, 2002). The factor that
constitutes construction cost overrun varies from one project to the other due to scope, size
and complexity of the project (Kasimu, 2012:775). Koushki et al. (2005:285) found that
contractor related problems, material related problems and owners’ financial constraints
were main causes of cost overrun in Kuwait’s private residential projects. A survey was
carried out among key stakeholders (contractors, consultants and client organisations) in
Nigeria. It was found that poor planning, shortage in materials, imported materials, changes
in site conditions, design changes were the main causes of construction delays and cost
overrun (Mansfield et al., 1994:254).
Baloyi and Bekker (2011: 55) highlighted some the factors that causes cost overrun in
construction project as change in the price of construction materials, additional work and
delayed constituted by contractors. Further, Kasimu (2012: 779) noted that the most
significant factors that result to cost overrun in building construction are condition of the
market, experience of contractor, time constraint and political situation. A study conducted
by Olawale and Sun (2010: 522) relative to the construction industry in United Kingdom
reveal the top five factors inhibiting time and cost control in construction practice as design
changes, risks and uncertainties; inaccurate evaluation of project time/duration; complexity
of works and; non-performance of subcontractors. Similarly, Al-Juwairah (1997:192)
conducted a study to identify factors affecting construction cost in Saudi Arabia, 42 factors
were identified in the study. The top five major factors affecting construction costs from the
contractors’ perspective were: cost of materials, incorrect planning, contract management,
wrong estimation method, and previous experience in contract. Furthermore, Mahamid et al.
(2012:70) conducted a survey using data from Palestinian road construction projects
awarded over the years 2004 to 2008 to investigate the statistical relationship between
actual and estimated cost of road construction. The survey was based on a sample of 169
road construction projects. The findings revealed that 100% of projects suffer from cost
diverge, it was also found that 76% of projects have cost under estimation and 24% have
33
cost over estimation. The discrepancy between estimated and actual cost has an average of
14.56%, ranging from -39.3% to 98%. Consequently, the South Africa construction industry
also experienced notable cost overruns in several large scale projects; Johannesburg’s
soccer stadium experienced a cost overrun of 58%. Notably, Greenpoint stadium in Cape
Town experienced a 50% cost overrun. Durban stadium also experienced a cost overrun of
38% (Ramadodu & Verster, 2010:135). In addition, Prajapati, Gupta and Pandey
(2016:1349) conducted a study to investigate the cost overrun in school building construction
project. The study identified 26 factors as critical factors out of 41 cost overrun factors
identified in the study. Hence, the top five factors affecting cost overrun in building
construction projects are political situation, fluctuation of prices of materials, level of
competitors, currency exchange, and economic instability. Nega (2008:106) noted inflation,
increase in the cost of construction materials, poor planning and coordination, change orders
due to enhancement required by clients, and excess quantity during construction as the
most important causes of cost overrun in building construction projects in Ethiopia.
2.6.4 Time overrun in construction project
According to Kaming et al. (1997:83), a time overrun is defined as the extension of time
beyond planned completion dates. However, time overruns can occur in any or all phases of
a construction project thereby increasing total project duration (Yang & Ou, 2008:323).
Memom et al. (2011:54), with a survey distributed amongst project management consultants,
discovered that the dominating factors causing time overruns are cash flow and financial
difficulties faced by contractors. In addition, Olawale and Sun (2010:84), in their studies of
high-rise projects, found the most important factors causing time overrun to be design
changes, poor labour productivity, inadequate planning and resource shortages. Further, in
their study, Ade-ojo and Babalola (2013:5) identified six major causes leading to schedule
overruns, ranked as follows: 1) design error; 2) poor site condition; 3) delay in payment; 4)
financial incapability of client; 5) financial incapability of contractor; and finally 5) non-
availability of subcontractor and supplier.
Delays are inevitable and appear in every construction project, with causes of these delays
varying considerably from project to project (Koshe & Jha 2016:20). Finding from previous
studies (Hanna et al., 2004:763; Sambasivan & Soon, 2007:517) have shown that delay in
projects has positive and linear relationship with the increase in cost. Similarly, le-Hoai et al.
(2008:369), studying problems related to delays and cost overruns during construction
phase, noted financial difficulties of owners and contractors, poor project management
assistance, design changes, poor site management and supervision, and financial difficulties
of contractor as the most severe, common causes identified for delays and overruns. To
34
buttress this, Koshe and Jha (2016:28) identified 88 major factors that cause delay in the
Ethiopia construction, categorising the factors into eight major groups. Their investigation
showed that contractor financial difficulty was the most influential factor causing delays in
construction. Table 2.1 illustrated the factors responsible for cost and time overruns used in
this research.
Table 2.1: Factors responsible for cost and time overrun
Factors
Supported by
Contractor related problems
Koshe & Jha (2016); le-Hoai et al. (2008); Ade-ojo & Babalola (2013); Baloyi & Bekker (2011); Olawale & Sun (2010); Kasimu (2012): Koushki et al. (2005); Kasimu (2012)
Design changes le-Hoai et al. (2008); Ade-ojo & Babalola (2013; Nega (2008); Olawale & Sun (2010); Kaming et al. (1997): Mansfield et al.( 1994)
Poor planning Mansfield et al.( 1994); Nega (2008); Kaming et al. (1997); Al-Juwaireh (1997)
Fluctuation in the cost materials
Baloyi & Bekker (2011); Al-Juwaireh (1997); Nega (2008); Prajapati et al. (2016)
Political situation Kasimu (2012); Prajapati et al. (2016)
Wrong estimation Al-Juwaireh (1997), Mahamid et al. (2012)
Shortages of materials
Mansfield et al. ( 1994); Kaming et al. (1997)
Condition of the market
Kasimu (2012); Prajapati et al. (2016)
Financial constraint le-Hoai et al. (2008); Ade-ojo & Babalola (2013); Koushki et al. (2005)
Additional work Baloyi & Bekker (2011)
Change in site
Mansfield et al. (1994)
Time constraints Kasimu (2012); Olawale & Sun (2010)
Contract management
Al-Juwaireh (1997)
Currency exchange Prajapati et al. (2016)
Economic instability Prajapati et al. (2016)
Labour productivity Kaming et al. (1997)
35
A number of studies have been conducted to investigate the effects of cost overrun in
construction projects. Table 2.2 summarizes some of these effects, as presented in some
previous studies.
Table 2.2: Main effects of cost overrun in construction projects through previous studies
Effects Less profit
to client Less profit to
contractor Cash flow problem
Dispute End user
satisfaction Abandonment
Reference
Nega (2008:103)
Prajapati et al. (2016:1340)
Memon et al. (2011)
Sandasivan & Soon (2006:526)
Zainuddeen et al. (2008:9)
2.7 EFFECTS OF BUILDING MATERIALS COST ON HOUSING DELIVERY
In South Africa, the cause of increase in the cost of building materials resulted from the
combined effects of high energy cost, exchange rate, crude oil prices and imported duties
(Windapo & Cattell 2012:192). Jagboro and Owoeye (2004:11) and Aibinu and Jagboro
(2002:594) noted that increase in the cost of building materials has significant effects on the
industry as it leads to fluctuation in construction costs and the eventual abandonment of
projects. Similarly, Windapo and Cattell (2013:70) highlighted the effects that increases in
the cost of building material have on the construction industry: inability of developers to
deliver affordable housing, high tender valuations and poor construction industry
performance. Akanni et al. (2014) identified some possible effects that increase in the cost of
building materials have on delivery of housing: completion at the expense of other projects;
delay in progress of project works; other valuable projects not being commissioned; rate of
unemployment of construction workers; poor workmanship due to inadequate materials to
use; low quality local materials; and hindered implementation of innovation in construction.
2.7.1 Fluctuation in cost of construction
According to Windapo and Cattell (2013:70), substantial growth in the construction industry
is subject to price stability in materials costs as these have increased at faster rates than the
36
expected. Client and project contractors have been facing serious issues to maintain steady
cost projection on construction projects (Akanni et al., 2014:2). According to Ali and
Kamaruzzaman (2010:116), poor estimation of original project cost and underestimating the
construction cost by quantity surveyors are the basic reasons of cost escalation in
construction industry. The researcher further stated that the prices change so quickly that
the initial budget figures become completely unrealistic. Akanni et al. (2014:6), in their study
of the implications of the rising cost of building materials in Nigeria, determined fluctuation in
construction costs as the most significant effect of increase in the cost building materials.
This is in agreement with Windapo and Cattell (2013:75) who found, on the key issue
affecting the development of the construction industry in South Africa that increase in costs
of building materials was a significant factor affecting development of the construction
industry. This can be attributed to inflation. Inflation in the cost of building materials has
resulted in low and unreliable rates of profitability, having a detrimental effect on
performance of the industry in the area of innovations in construction methods and material
research, thereby hindering delivery for sustainable housing.
2.7.2 Increase in project abandonment.
Haseeb et al. (2011:35) referred to the total abandonment of a construction project as
stopping every work or suspending the project for a long time. Numerous construction
projects are temporarily or even permanently abandoned, and according to Haseeb et al.
(2011:35), the predominance of many uncompleted and abandoned projects resulted from
finance related crises and material related factors. Ayodele and Alabi (2011: 144) and Idoro
and Jolaiya (2010) identified inflation and high cost of building materials as major factors that
lead to uncompleted and sub-standard buildings. The researchers further affirmed that this
has a significant effect on the industry for delivery of housing. Whereas Aluko (2008:20)
stated the effects of abandoned project on environment and identified such effects as the
problems of flooding, traffic congestion, air and water pollution, drug addiction and health
hazards in the neighbourhood, a later study conducted by Akanni et al. (2014:5) revealed
that an upward review of contract sum leads to conflicts between contractors and clients,
likely leading to cases of abandonment where investments are tied down, since such project
will not be put to use at the expected time.
2.7.3 Low volume of construction product
Output of the construction industry in South Africa is quite low when compared with the
construction industry in many developed countries. Ganiyu (2016:27) stated that the South
African construction industry is faced with a number of threats, primarily affecting its
performance in sustainable housing delivery. Similarly, in the studies of Windapo et al.
37
(2004:640), in Nigeria millions of middle and low-income families are being priced out of the
market for home ownership due to this excessive increase in the cost of building materials
and the consequential acute shortages of housing. The observations from these studies
were due to the increase in the cost of building materials. Anosike (2009:38) confirmed that
Nigeria has more than 17 million in housing deficit as of 2004.
2.7.4 Poor quality of workmanship
According to Lam, Chan, Wong and Wong (2007) output of quality buildings and structures
is one of the attributes of a developed construction industry. The quality of workmanship in
construction work is assessed according to the requirement of the relevant standard, and
marks are awarded if the workmanship complies with this standard (CIDB, 2011). The study
of Oladipo and Oni (2012), reporting the trend in the cost of building materials, has
envisaged great danger for the construction industry and the nation’s economy. The
researchers further claimed that there were records of conflicts between clients and building
contractors over review in contract sums, so to avoid conflicts and still be in the business,
some contractors fell back upon substandard or insufficient materials for construction
projects, an action which contributed to cases of building collapse. Undeniably, workmanship
plays an important role in project quality (Iwaro & Mwasha, 2012). Akanni et al. (2014:6)
further revealed low quality workmanship and inhibited innovations in construction methods
as further repercussions of building materials cost increases. Hence, the studies revealed
that increases in the cost of building materials contribute to low and unreliable rates of
profitability of contractors as attempts to balance up by enticing contractors to employ low
quality workmanship, prohibiting new innovations in the construction methods.
2.7.5 Unemployment of construction workers
Construction industry workers are extremely varied, as the industry is comprised of a wide
range of both skilled and unskilled workers (Akanni et al., 2014). Ayodele and Alabi (2011)
found that inflation in the cost of building material is killing the construction industry as many
contractors are unable to accurately forecast expected profit on the project, a situation that
has contributed to laying-off of workers and closure of firms in some extreme cases. Oladipo
and Oni (2012:133) supported this notion by stating that macro-economic indicators have an
effect on the cost of building materials which has contributed to unemployment. Akanni et al.
(2014:6) also revealed that reduction in the employment of labour workers in the
construction industry is most likely to impact the nation’s gross domestic product (GDP),
thereby reducing the contributions of the construction industry to the nation’s economy.
38
2.8 Selection of sustainable building materials
Building and construction activities worldwide consume three billion tons of raw materials
each year and represent 40% of total global use (Hamner, 2007:25). Sustainability goals
may be achieved by considering factors such as environmental impact, economic impact,
customer requirements and market demand (Ljungberg, 2007:466). However, building
materials are usually selected through functional, technical and financial requirements.
Therefore, to achieve economic benefits in the construction industry, it is essential to note
that a building is characterized by the materials used in its construction and should be
selected in conformity with principles of sustainability (Abeysundara, Babel, & Gheewala,
2009:998). Conversely, an inappropriate selection of materials may prohibit the
accomplishment of the desired sustainability goals (Florez et al., 2010:1). In fact, an
appropriate approach of selecting sustainable materials has been identified as the easiest
way for designers to begin incorporating sustainable principles in building projects (Godfaurd
et al., 2005:34). The environmental impact of materials needs to be carefully evaluated for
developing sustainable materials. The Life Cycle Assessment (LCA) method is a common
technique for evaluating environmental impact associated with material products (Bovea &
Gallardo, 2006:209) as it takes into consideration all the phases of a product’s life cycle.
Life cycle assessment ratings at each phase of building are essential for building
sustainability (Ljungberg, 2007; Karana et al., 2010). The Life cycle design principle is a
platform for the selection of building materials, encompassing the manufacturing process,
installation and even end use and disposal are inspected for environmental impact.
According to Kim and Rigdom (1998:7) material life cycle is divided into three phases:
the pre-building phase;
the building phase; and
the post-building phase.
The pre-building phase encompasses the discovering, manufacturing and delivering as well
transporting of materials needed for construction to the point of use. This phase is critical
and thus must be intentionally selected due to its strong impact on the environment (Kim &
Rigdom, 1998:7). Therefore, full knowledge of environmental consequence of this phase is
required in order to select the best building materials for construction. If this phase is not well
managed during extraction, a negative impact on the environment is likely (Ljungberg,
2007:466).
39
The building phase describes the usefulness of building materials in a building. This phase
comprises construction and maintenance of materials; waste generated during construction
can be recycled (Kim & Rigdom, 1998:11). The post-building phase results from decisions
made during the building phase in terms of waste disposal (recycling or reusing). These
phases are likely to be sustainable (Ljungberg, 2007:466). Figure 2.5 illustrates the
procession of the phases of building.
Pre-Building Phase Building Phase Post Building Phase
RECYCLE
RE-USE
WASTE
Manufacture
Extraction
Processing
Packaging
Shipping
Use
Construction
Installation
Operation
Maintenance
Disposal
Recycling
Re-use
.
Figure 2.5: The building materials life cycle phases
(Adapted from Kim & Rigdon, 1998:8)
In order to attain sustainability in building and stakeholder satisfaction, the process of
discovering raw materials as well as extracting materials, processing and usage are
essential (Florez, Castro & Irizarry, 2010:2). Moreover, the durability and functionality
(aesthetics, health enhancement, use of space) of the building depends on adequate use of
quality building materials (Karana, Hekkert & Kandachar, 2010:2933). Thus, the materials
selection phase is vital and should be adopted during construction.
2. 8.1 Principles of material selection towards sustainable construction
Material selection in sustainable building production is defined as the process of choosing
materials that suit the design criteria such as function, shape, cost and cultural aspects of
the building (Karana et al., 2010:2932). According to Alibaba (2004:307) and Nasar et al.
(2003:543), one of many factors that impact the sustainability of building delivery is selection
of building materials. Notably, material selection could be done in different ways, but the
principles are similar. Kibert (2012:7), for example, posited some principles to achieve
sustainability in a project as guidelines for materials selection:
environmental impact;
market demands/ trend;
material life cycle cost;
40
functional and structural demands;
dematerialization in design;
socio-economic impact;
material efficiency (use of renewable and recyclable materials);
building design; and
technological impact.
Lyungberg (2007:469) also highlighted some guidelines for material selection: material
overview, recycling, market aspect, customer demand and dematerialization. In addition,
Baharetha et al. (2012:732) claimed the attributes that designer should incorporate when
selecting sustainable materials include durability, recyclability, energy efficiency
maintainability, and use of locally made materials to lessen the deleterious environmental
consequences on construction. This cannot be done without carefully understanding the
scope, nature and complexity of a construction project. Furthermore, Abeysundara et al.
(2009:999) listed functionality, social issues, cost, aesthetics, density, temperature stability,
material strength and durability as important factors that influence the selection of materials.
Clearly, the selection of materials at the early stage will enable designers to uphold
functional requirements of a building using the best available materials and to develop a
feasible plan for achieving the specified design and structure (Deng & Edwards, 2007:131;
Rao, 2008:1949).
Zhou et al. (2009:1209) posited some factors to be incorporated by designers when
selecting a material in Figure 2.6, the designer must consider fulfilling the three basic
properties: mechanical properties, economic properties and environmental properties.
According to these researchers, economic property is the most important aspect in material
selection. Purchase cost, process cost, transportation cost and recycle/disposal cost are the
four factors considered under economic property. Additionally, mechanical properties are
especially important because they are indicators of strength, density, stiffness, and
hardness. And finally environmental property should not be neglected for the consideration
in the selection of sustainable building materials.
41
Evaluation indicators of material selection
Mechanical properties
Economic properties
Environmental properties
StrengthStiffnessToughnessHardnessDensity
Purchase costProcess costTransportation costRecycle/ Disposal cost
Environmental pollutionEnergy consumptionRecycle &Re-useBreakdown
Figure 2.6: Evaluation indicators of material selection
(Adapted from Zhou et al., 2009:1210)
2.8.2 Criteria for selection of sustainable building materials
In deciding the type of building material to use in a particular application, it is vital to know
the criteria for selecting such materials (Akadiri & Omolaiye, 2012:671). Basically, with the
growing number of building materials available, each has specific functional demands and
complex assembly requirements for building construction (Sharma & Mehta, 2014: 81).
Building construction is a major contributor to greenhouse gas emissions and global
ecological degradation. Hence, in order to sustain the urban future and to prevent
environmental damage, protect natural resources and improve the health of ecosystems, a
wise choice of materials is imperative (Sharma & Mehta, 2014:80). The overall method for
selecting building materials can be broadly divided into five categories (Froeschle, 1999):
resource efficiency;
energy efficiency;
water conservation;
indoor air quality; and
affordability.
42
2.8.2.1 Resource efficiency
Resource efficiency simply means the efficient use of materials, energy and natural
resources so as to produce materials with reduced resources and environmental impact
(Ruska & Häkkinen, 2014:267). Notably, Abeysundara et al. (2009) emphasised that the
selection of materials should be based environmental impact of the materials, and this
should be incorporated at project initiative and design phases. According to Sharma and
Mehta (2014:82), resource efficiency can be made proficient by using material that run into
one or more of the following criteria: recycled content, naturally plentiful or renewable,
resource efficient, locally available, salvaged, refurbished, or remanufactured, and certainly
durable. Akadiri (2011:115) stated that the significance of reusing and recycling the building
parts is the saving energy. He further verified using recycled materials to produce new
building materials consumes less energy than using new materials. The reuse of building
materials is a substitute for the reduction of construction and demolition waste (CDW) when
renovating and demolishing building (Da Rocha & Sattler, 2009). Therefore, reuse and
recycling appears to be an approach worthy of consideration for embracing sustainable
practices, as it contributes significantly to waste reduction in the building process.
Natural materials usually have less embodied energy and toxicity than artificial materials
(Godfaurd et al., 2005). The use of sourced locally building materials can help to reduce
environmental damages, reduce air pollution and reduce transport distances (Akadiri,
2011:117). Combining natural materials into building products increases the sustainability of
the products (Godfaurd et al., 2005).
Increasing material durability will also improve the sustainability of a building (Akadiri,
2011:116). The more durable the material is, the less time and fewer resources required to
maintain it. Over the building’s lifespan, a less often replaced durable material requires
smaller amounts of raw material and will produce less landfill waste (Akadiri et al., 2012).
2.8.2.2 Energy efficiency
Energy efficiency is an important feature in enhancing the environmentally sustainability of
materials (Arora, 2009). Thus, major aim of using energy efficient materials is to lessen the
amount of generated energy in a building. Energy efficiency can be best realised by using
materials, components and systems that lessen energy intake in buildings and facilities
(Sharma & Mehta, 2014:82).
43
2.8.2.3 Indoor Air Quality (IAQ)
In order to meet the needs of the present without compromising the ability of future
generations to meet their own needs, taking cognizance of the quality of air we breathe
inside the building has gained considerable attention over recent decades (Niu & Burnett
2001). Materials applied in the interior of a building can be source of pollutants, significantly
affecting the indoor air quality which in turn is harmful to the health and comfort of building
occupants (Arora, 2009). According to Mehta & Sharma (2014:82), indoor air quality can be
improved by using materials that adhere to the following criteria: low or non-toxic, minimal
chemical emissions, low-voc assembly and moisture resistant.
2.8.2.4 Water conservation
Materials that have water conservation features help in reducing the amount of water used
on site. In addition, water consumption can be monitored and capped in buildings and
landscaped areas by making use of products, materials and systems that reduce water
consumption as well as increasing water recycling and reuse ( Sharma & Mehta 2014:82).
Kim and Rigdon (1998) highlighted examples of ways by which water can be conserved, by
controlling the amount of water through a fixture and recycling water that has previously
reached the site or been used. Thus, recycled gray water from sinks, showers and laundry
can be re-designated to flush toilets. Using water resourcefully and reducing the amount of
water used will aid in the much-needed conservation of freshwater (Arora, 2009:36).
2.8.2.5 Affordability
Sustainable building materials are said to be affordable when less costly than counterpart
conventional building materials or within budgeted construction cost as well as low life cycle
cost (Mehta 2015). Cost related with energy, replacement and maintenance costs are
significantly reduced with the adoption of LCC and essential application of green
construction practices (Shannon et al., 2005). The LCC method is mainly applicable in
determining the cost of a building which is economically reasonable with reduced use cost
when compared with another building which has lower initial cost but greater use cost in
terms of maintenance, operating, replacement and repair (Arora, 2009:38).
2.8.3 Cost efficiency
The theory of sustainability in regard to construction of buildings relates to the effectiveness
cost and to reducing investment costs (Akadiri et al., 2012). Client demand on standard
quality, lower cost and timely delivery of project has been a considerable problem within the
construction industry. In order to meet client demand, secure better contract and investment
44
return, construction stakeholders should adopt cost efficiency strategies (Dzeng & Wu,
2012). Collectively, owner, user and societal concern is primarily on the enhancement of cost
efficiency of the building structures Akadiri (2011). Thus, the researcher explains the
application of life cycle cost (LCC) as an important measure for carrying the client alongside
at early design stage. Castillo and Chung (2004) similarly stressed that the life cycle cost of
a building consists of maintenance, energy and repair costs. Akadiri (2011) revealed that
measuring the importance of sustainable construction from a cost viewpoint requires more
than usual life cycle costs and include usage costs and consideration of all stakeholder
costs.
2.9 Chapter summary
This chapter presents reviewed literature on identified factors responsible for increase in the
cost of building materials. Literature revealed the impact of several factors – economic
related factors, building production related factors, stakeholder related factors and external
related factors – on the cost of building materials. The literature review revealed the effects
of increase in the cost of building materials on housing delivery. Consequently, this chapter
encapsulates criteria to be considered in the selection of sustainable building materials. In
an attempt to proffer solutions to these challenges, literature revealed that in regard to those
factors responsible for increase in building material cost, there is a clear need for appropriate
policy legislation by government. Securing reduced material cost at optimum quality and time
towards client satisfaction is considered a necessary major focus of the construction
industry.
45
CHAPTER THREE
RESEARCH METHODOLOGY AND DESIGN
3.1 INTRODUCTION
The impact of research method on the outcome of any research work cannot be
overemphasized. The earlier chapter provided a review of existing literature in line with
research objectives towards achieving the goal, the aims and objectives, of this present
research. According to Dahllerg and McCaig (2004:64), research methodology is an
approach undertaken in research in line with an extension of aims and objectives of
research. Thus, the research methodology segment is a podium for researchers to validate
their research method decisions in achieving the research objectives by way of answering
the research questions.
This chapter discusses the various types of research methods and specific research design
adopted for this study. The research instruments, designed to achieve the research
objectives, are ultimately to proffer solutions to the research questions highlighted in Chapter
One of this study. Thus, this chapter comprises research approaches, design, sampling
techniques, data collection scheme, techniques adopted for data analysis, and essentially
the test of validity and reliability of the research instrument.
3.2 Research philosophies
Full knowledge of the research philosophies that underpin various principles of research is
important for researchers. Hence, Easterby-Smith et al. (2012:17) highlighted three
imperative factors of philosophical issues in research:
It helps researcher recognize and create design that may be outside the researcher’s
previous knowledge.
Knowledge of philosophy helps the researcher to identify which design will work and
which will not work.
It helps to explain research design.
Solanke (2015:95) is of the opinion that the philosophical stance of a research study guides
and validates the researcher’s verdicts. Thus, his philosophical pillars of research include the
following:
46
positivism (realist); and
interpretivism.
3.2.1 Positivism
Positivism is attained by the ability of a researcher to test hypotheses derived from
obtainable theories by observations or measurements of social realities (Flowers, 2009).
Additionally, positivism is a term used to refer to the quantitative nature of a research
(Biggam, 2011). Thus, positivism favours a quantitative approach, relying primarily on
experiment, survey, questionnaire for data collection and analytical statistical analysis. The
qualitative approach would not fit easily within the positivist approach to research. The view
of positivism maintains that objects of social sciences, namely people, are suitable for the
implementation of scientific methods. Similarly, Henn et al. (2006:6) connects positivism
straight to the scientific model. Furthermore, the researchers stated the logic of positivist
research philosophy as follows:
knowledge centred on what can be verified by scrutiny of tangible evidence;
seeks to identify processes of cause and effect of phenomena to test theory;
use of scientific method that stresses control, objectivity and standardization.
3.2.2. Interpretivism
Interpretivism is a method that aims to understand people (Babbie & Mouton, 2005). The
interpretivism paradigm of research is concerned with the use of unstructured qualitative
approaches in the collection of data, including comprehensive interviews with participants
(Henn et al., 2006:14). Thus, the fundamental idea of the interpretivism paradigm in research
is to work with subjective meaning already in the social world by exploring the complexity of
social phenomena, avoiding distortion, gaining understanding as well as incorporating block
theory in a building (Goldkuhl, 2012:5).
The interpretivist philosophy of research is based on four assumptions, as identified by Burr
(2003):
It presents a critical stance and scrutiny on hidden, forgotten or undiscovered
knowledge (objective information).
The languages used for data interpretation are derived from social interaction with
the participants in a particular place and time.
The knowledge derived is sustained by qualitative methods and social relations with
participants.
47
Subjective knowledge and social processes and actions are relative.
3.3 Research methodology
Mouton (2001:56) views research methodology as concentrating on the research process
and the type of tools and procedures to be applied. Similarly, Leedy and Ormrod (2010)
described research methodology as a step-by-step process of conducting a research in a
particular study. Furthermore, the researchers specified the primary purposes of the
research methodology as follows:
to set a standard for data acquisition; and
to collate the data after acquisition and give interpretation.
3.3.1 Quantitative research method
Creswell (2009:146) defined quantitative research as ‘an inquiry into a social or human
problem, based on testing a hypothesis or theory composed of variables, measured with
numbers, and analysed with statistical procedure to determine whether the hypothesis or
theory hold true’. Furthermore, quantitative research is a logical process of using numerical
data from a designated sample group of a population to generalize the findings to the
population of study (Maree & Pieterson 2007). Hence, the process of the quantitative
research method involves clearly stating and presenting research questions to respondents
designed to answer the research objectives (Dahlberg & McCaig 2010:159). To that end,
Maree and Pieterson (2007) and Flick (2015) explained that this research method is
characterized by three elements:
objectivity;
numerical results(data); and
generalisability.
Akadiri (2011:173) identified the three types of quantitative research as experiments, quasi-
experiments and surveys. The nature of the research depends mainly on types of techniques
selected. The survey technique is the most widely use method in social science and also the
most relevant to this study. Typically, the quantitative method makes use of a questionnaire.
Quantitative research always involves the numerical analysis of data gathered by means of
some kind of structured questionnaire. The most common of this technique are mail (use of
online Survey Monkey), personal and telephone survey (Rubin & Babbie, 2010; Creswell
48
2009:148). Table 3.1 collates the advantages and disadvantages of these three data
collection methods.
Table 3.1 Advantages and disadvantages of survey methods
Types of Survey
Advantages Disadvantages
Mail survey • Cost is low compared to other methods • High degree of respondent anonymity • Wide geographical reach • Relatively low cost of processing
• Low rates of response • Require easily understood questions and instructions • Lack of chance to probe for further or clarity of answers • Greater respondent bias • High rate of uncompleted questions
Personal survey • Allows high flexibility in the questioning process • Interviewers have control of interviewing situation • High response rate • Possibility of collecting supplementary information
• Higher cost than mail questionnaire • Potential interviewer bias due to high flexibility • Lack of anonymity; hesitant to disclose personal data • Time consuming
Telephone survey • Moderate cost • Increased speed and time of data collection • High response rate • Increased quality of data
• Hesitancy to discuss sensitive data on phone • High chance of respondents terminating interview earlier • Less chance for supplement information
(Adapted from Rubin & Babbie, 2010)
3.3.2 Qualitative research
Qualitative research method deals with the technique for exploring and understanding the
meaning of individuals or groups ascribe to a social or human problem (Olayinka, 2015:150).
In addition, the qualitative research method involves the effort of collecting in-depth
descriptive data concerning a particular phenomenon with the purpose of improving
knowledge (O’leary, 2010:105). Furthermore, Amaratunga et al. (2002:20) stress that
qualitative researchers investigate the opinions, beliefs, understandings and views of the
respondents, and to this end, the qualitative research method includes the use and collection
of various empirical data: an interview, life story, observations and historical studies
(Creswell & Clark 2007).
49
There are several advantages and disadvantages involved in using a qualitative research
method. Flick (2015:12) and Kumar (2011:114) listed a few examples of advantages:
It allows for detailed and exact analysis of a few case in which participants have
much more freedom to determine issues that are relevant in the context.
The main strength of qualitative research is the ability to study phenomena not
available elsewhere.
Fellow and Liu (2008:27), Flick (2015) and Bryman (2012:382) presented the disadvantages
qualitative research: it takes a great deal of time to collect data and the analysis requires
some degree of interpretation, which may be subject to bias and personal subjectivity; and
that a variety of external environmental variables are likely to impact the data and the
results. A comparison of both qualitative and quantitative research epistemology are shown
in Table 3.2
Table 3.2: Comparison between qualitative and quantitative research
Point of comparison
Qualitative research Quantitative research
Alternative labels Constructivist, naturalistic-ethnographic or
interpretative
Positivist, rationalistic or
Functionalist
Scientific
Explanation
Inductive in nature Deductive
Data classification Subjective Objective
Objective/ purpose To gain understanding of underlying reasons
and motivations
To provide insight into the settings of a
problem, generating ideas and /or hypothesis
for later quantitative research
To uncover prevalent trends in thought and
opinion
To quantify data and generalise
results from a sample to the
population of interest.
To measure the incidence of
Various views and options in a
chosen sample
Sample Usually a small number of non-representative
cases
Respondents selected to fulfil a given quota or
requirement
Usually a large number of cases
representing the population of
interest.
Randomly selected respondents
Data collection Participant observation, semi and
unstructured interviews, focus groups,
conversation and discourse analysis.
Structured interview, self
administered questionnaires,
experiments, structured
observation, content analysis /
Statistical analysis
50
Data analysis Non-statistical Statistical usually in the form
of tabulations
Findings are conclusive and
usually descriptive in nature
Outcome Exploratory and / or investigative.
Findings are not conclusive and cannot be
used to make generalisations
Used to recommend a final
course of action
(Source: Amaratunga et al., 2002:20)
3.3.3 Mixed method research
Mixed method research involves the adoption of philosophical assumptions in the collection
and analysis of both quantitative and qualitative data in a single research work (Creswell &
Clark 2007:114). In other words, mixed method research combines or mixes quantitative and
qualitative research in the same study or series of studies in collection of data, analysis and
inferences (Swanson & Holton, 2005; Johnson, Onwuegbuzie & Turner, 2007:123: Teddlie &
Tashakkori, 2009:4). The fundamental notion is that the combination of qualitative and
quantitative approaches provides a broader understanding of a research problem than either
approach alone (Olayinka, 2015:158). Hence, mixed methods help to highlight differences
and similarities between specific features of phenomena. Researchers adopt mixed
methodological approach with the interest of combining qualitative and quantitative research
pragmatically, mainly to compensate the paradigm shortcomings in the two approaches
separately (Flick, 2015).
The merits of integrating the qualitative and quantitative method postulated by Eaterby-Smith
et al. (2012:63) are listed in section 3.3. However, despite the advantages of the mixed
method research, researchers are faced with some challenges in the course of their
research. These challenges, according to Eaterby-Smith et al. (2012:63), are detailed in
Table 3.3.
51
Table 3.3 Strengths and challenges of mixed methods
Strengths Challenges
• Increased confidence and credibility of results
• Increased validity
• Stimulate creative and inventive methods
• Can help synthesis and integration of theories
• May serve as critical test of competing theories
• Can combine confirmatory and exploratory
research simultaneously
• Presents greater diversity of views
• Provides better inferences
• Replication is difficult to achieve
• Research design must be relevant to research
question
• They provide no help if the research ask the wrong
questions
• They require more resources than single method
studies
• Their use requires a competent overall design
• Researcher needs to be skilled in the use of both
methods
• It is not helpful if one method simply provides window
dressing for the other
(Adapted from Eaterby-Smith et al., 2012:63)
3.4 Research approach
3.4.1 Deductive approach
The deductive approach tests the validity of assumptions (or theories/hypotheses) on hand
(Bryman & Bell, 2015:27). According to Dahlberg and McCaig (2010:20), the deductive
research approach involves the process of generating hypotheses from a general truth or
statement to reach a definite conclusion. Therefore, a deductive approach to research
consists of logical arguments which originate with general statements with the purpose of
obtaining a particular conclusion (Solanke, 2015:97). The deductive research approach is
principally used in quantitative research (Bryman, 2004:20).
3.4.2 Inductive approach
The inductive approach involves the process of beginning with a particular observation or
finding and thereafter general conclusions are derived as results (Walliman, 2012). Hence,
this is a ‘bottom up’ research approach, contributing to comprehension of reality first and
ultimately producing a theory (Dahlberg & McCaig, 2010:20). The inductive approach is
mostly used for scientific research. Notably, the process of induction involves drawing
generalisable inferences out of observations (Bryman 2012:26). Figure 3.1 endeavours to
capture the core difference between the inductive and deductive approaches.
52
Theory
Observations/Findings Theory
Observations/Findings
Deductive approach Inductive approach
Figure 3.1 Deductive and inductive research approaches
(Source: Bryman, 2012)
Walliman, (2005) further clarified that an inductive (generalized) result can only be regarded
legit if it satisfies the following conditions:
a large size of population for survey or observation is used;
the observation or survey is coordinated repeatedly under different conditions; and
the derived observed empirical data corresponds with the generalized result.
3.5 Research strategies
Findings from previous studies (Walliman, 2012; Leedy & Ormrod, 2010; Walliman, 2005)
showed various research strategies for the usage of qualitative, quantitative and mixed
research methods. Research strategies include case studies, structured interviews,
phenomenological studies, historical research, action research, experimental studies, quasi-
experimental studies and theoretical research studies (Bryman, 2012; Biggam, 2015;
Walliman, 2012; Leedy & Ormrod, 2010; Creswell et al., 2007).
3.5.1 Survey research
O’Leary (2010:181) defined survey research as “the process of data collection by asking a
selected set of individuals the same questions based on their characteristics, attitude and
ways of living by administering questionnaires”. Thus, survey research serves as an efficient
and effective means of looking at a far greater number of variables than possible as
compared with experimental approaches, and is one of the most commonly used methods in
social sciences to provide a descriptive sample of the area of study (Akadiri, 2011:181).
Moreover, Cohen, Manion and Morrison (2001) and Henn et al. (2006:126) articulated that
the basic aim of the survey research is to “explore, understand and interpret phenomenon(s)
53
which exists presently”. Therefore, survey research involves drawing information from
respondents which can be achieved through questionnaires or structured interviews for data
collection, with the aim of generalizing from a sample to a population (Babbie, 1990;
Creswell, 2009). Maree and Pieterson (2007) enumerated the following as characteristics of
survey research:
large sample size;
numerous variables measured to generate related hypothesis for testing; and
results that can be generalised.
3.5.2 Action research
Mcniff and Whitehead (2011:8) describe action research as “a form of enquiry that enables
practitioners in every job and work of life to investigate and evaluate their work”. Kumar
(2011:131) states that most action research is directed towards improving quality of service
by identifying areas of interest, developing, testing alternatives and experimenting with a
new approach. Notably, to effectively conduct action research, the researcher must possess
the ability to understand and interpret the problems faced in order to offer possible and
practical solutions (Kumar, 2011:132). Thus, action research, according to Ferreira
(2007:124), is characterised by the following;
It seeks to derive solutions to practical issues.
It is aimed at effecting a change.
It is an interactive strategy to knowledge development.
It is a cyclic research process of planning, solution implementing and reasoning.
It requires the participation of the research sample and the researcher(s).
3.5.3 Case study
Case study research is concerned with the complexity and particular nature of the case in
question (Bryman, 2012:66). Similarly, case study research refers to units of investigation
that are studied at different levels, such as individuals within a community, a group of
people, an organisation or a phenomenon (Henn et al., 2006:58). Barbour (2008:61)
expresses the advantage of adopting single case study is that there is a possibility of closely
scrutinising the case under study. Thus, case study research involves the study of a single
case, documentation, interviews, comparative studies (multiplicity of cases) or retrospective
studies using historical sources (Flick, 2011:70).
54
3.5.4 Historical research
Maree and Pieterson (2007) defined historic research as a systematic holistic process of
describing, analysing and interpreting past scenarios based on information derived from a
selected population. Similarly, Leedy and Ormrod (2010) defined historical research as an
effort undertaken by a researcher to interpret historic events through the collection and
analysis of relevant historic documents or oral histories. Therefore, historic research calls for
the researcher to give critical, analytical scrutiny of reports, documents or minutes about an
event or incident (Nieuwenhuis, 2007). Nieuwenhuis broadly enumerated four types of
historic research useful in general research:
primary sources (achieved documents or other original sources);
secondary sources (works of other scholars on the focus of study);
running records (documentaries maintained by organisations); and
recollection (including oral histories and autobiographies).
3.6 Questionnaire development
A questionnaire is a tool for data collection containing questions and statements prepared to
acquire information from research respondents (Adler & Clark, 2008:216). Moreover, a
questionnaire survey is one of the most cost effective ways to involve a large number of
people in a research process to accomplish more thorough results (McQueen & Knussen,
2002). Poorly designed questionnaires generate only unsatisfactory or inadequate data that
cannot be properly interpreted (Dahlberg & McCaig, 2010:179). This necessitates the need
for certain precautions to be taken into consideration when designing questionnaires: the
questions must be clear and easily understood by the respondents; it should be easy to
administer by the interviewer; the recorded answers should be easily edited, coded and
transferred onto a computer file for statistical analysis; and its flow, length and structure must
motivate respondents to complete the questionnaire (Akadiri, 2011:182). Akadiri stated that
questionnaires are of various forms, but mainly divided into two categories:
open-ended questions (respondents record their views and opinion in full); and
Closed-ended questions (respondents choose from a given set of answers).
3.6.1 Open-ended questions
Open-ended questions are a form of questionnaire that does not give any particular guide to
likely responses. Thus, the respondents are allowed to record their opinion to a particular
question in their own words (Kumar, 2011:151). Open-ended questions are suitable and
55
appropriate for a study, for example, that plans to explore the way respondents think, and
discover what is really important to respondents with the asking of questions which have
many possible answers (Neuman, 2000:260). The following, according to Maree and
Pieterson (2007) and Leedy and Ormrod (2010), are advantages and disadvantages of
open-ended questions:
Advantages
Participants respond to questions honestly, assured of being anonymity.
Respondents’ opinions are clearly revealed.
Complex questions are duly answered with detailed justifications.
Disadvantages
Data coding poses to be difficult.
A great deal of time is required for the respondents to complete (thinking and writing).
Answers are variable in content as a result of unstructured nature of questions.
The use of statistical analysis in this design has proven abortive.
3.6.2 Closed-ended questions
Closed-ended questionnaires offer a set of sequential questions, requesting respondents to
choose the most appropriate answers (Maree & Pieterson, 2007). Burns (2000:572) notes
that closed-ended questions have the advantage of attaining greater uniformity of
measurement and therefore greater reliability in guiding respondents to answer in a manner
fitting the response category. Leedy and Ormrod (2010) further buttressed that applying a
closed-ended question in research has the following advantages:
The questions are short, precise and easy to answer.
Coding and statistical analysis are easily done.
However, despite the numerous advantages of closed-ended questions, Maree and
Pieterson (2007) stated the following as disadvantages of closed-ended questions:
The answers are very simple with no background details
Respondents may be cajoled to give answers they would never have given.
Answering the questions are too easy, so answers given may mislead the
researcher(s).
56
Respondents’ opinions might not an option to choose from.
The questionnaires are typically too lengthy.
3.7 Research design
According to Leedy and Ormrod (2010), research design is holistic processes referring to the
general procedure of answering a research problem within a specified period of time (data
collection, analysis and selection of relevant empirical material). Similarly, research design
essentially implies the plan or strategy required for conducting a research work (Henn,
Weinstein & Foard, 2006:3). Leedy and Ormrod (2010) and Henn et al. (2006) identified the
following as characteristics of a reliable research design:
The design must aim at obtaining measurable data; that is, data derived must be
statistically based.
The design must be replicable by other researchers within the same parameters.
The research design must state the appropriate data analysis to be used and why.
The approach adopted for a research project is vital to the success or failure of any study
3.7.1 Research design for the study
Various studies have been undertaken to ascertain the effects of building material cost on
sustainable housing delivery. Ihuah (2015) and Akanni et al. (2014) recognised the
importance of analysing the role of sustainable building materials for construction works in
an effort to promote sustainable housings. This process enables site engineers to determine
how and when the project will be delivered. Notably, Akanni et al. (2014) noted that previous
studies on cost of building materials only identified the causes, with little emphasis on the
effect this has on delivery of housing. This present research project, then, by adopting a
mixed method approach, explores the perceptions of construction stakeholders and site
supervisors on the factors affecting the cost of building materials and its effect on housing
delivery. The mixed approach was adopted for this study because it provides a more
comprehensive perceptive of a phenomenon than either approach separately (Leedy &
Ormrod, 2010). This research method was adopted specifically because it allows the
opportunity to validate the data derived by using two or more research methods without bias.
The qualitative method was applied to evaluate the practice of sustainable construction.
Therefore, site supervisor opinions were obtained through semi-structured interviews. The
57
quantitative method, moreover, was used to collect data from construction stakeholders
(architects, quantity surveyors, engineers, construction managers, project managers and
materials suppliers) and contractors to identify the factors causing increase in the cost of
building materials, the effect on the delivery of affordable housings and the criteria to be
considered in the selection of sustainable building materials for optimum usage. The
research data was obtained with the aid of a structured questionnaire survey (quantitative
method), which was validated by conducting semi-structured interviews (qualitative method)
shortly after the questionnaire survey. The results and conclusions of this study are thus
reliable and generalisable.
3.7.2 Exploratory study
An exploratory study is fundamentals part of a research questionnaire design to gain more
insight into the research problem and to provide solutions to them (Dahlberg & McCaig,
2010). Hence, Creswell (2011) recommends at pre-testing of a questionnaire, including
groups within the larger group of potential research participants. Piloting the research tool
helped in determining the possibility of answering the research questions using the data
generated from the questionnaires, before proceeding to the main study. The questionnaire
used for the exploratory study was piloted amongst construction stakeholders and pos-t
graduate students from the department of Construction Management and Quantity
Surveying, Cape Peninsula University of Technology, to certify the significance of the tool to
the research. Neuman (2000:166) also emphasized that the use of pre-test or a pilot study
questionnaire can improve the reliability of research work. The retrieved questionnaires for
the exploratory study were analysed using Statistical Package for Social Science (SPSS)
package.
3.7.3 Population and sample size
A population is defined as a collection of people, items or animals considered for a research
study (Bryman 2004:87). Similarly, the term population is referred to the universe of units
from which a sample is to be selected from this population (Bryman, 2004:87). Thus, it is
important to note that the term population in research does not out-rightly refer to a group of
people being considered for study, but varies depending on the nature and field of the study.
For the purpose of this research, the issue to be addressed is the effect of building materials
cost on housing delivery. With that in mind, the populations considered are construction
stakeholders (architects, quantity surveyors, engineers, the government, construction
managers, project managers and materials suppliers) and contractors within the South
African construction industry.
58
Flick (2015) described the sample of any population in research as a minimised
representation of the larger population. The majority of survey participants are construction
professionals with extensive construction knowledge, skill and formal educational, with the
exception of site supervisors with minimum formal education but adequate construction
background. Site managers, contract managers, project managers, site supervisors,
architects, site engineers and quantity surveyors are the selected sample to represent the
population for the purpose of this study. The study sample is therefore unarguably a suitable
representation of construction stakeholders in South Africa.
3. 7.4 Sampling technique
O’Leary (2010) defined sampling as the process of breaking a large group of respondents
into sections with the purpose of deriving results concerning the larger group. Furthermore,
Maree (2007) indicated that sampling is the process of selecting randomly from a population
to obtain a general finding of the whole population. Thus, it is necessary to note when
conducting sampling that for a sample to represents a population, this is dependent on the
sample frame, sample size and sampling design (Fowler & Consenza, 2009; Leedy &
Ormrod, 2010). This research adopts purposive sampling techniques, considering the
complex nature of the construction industry in relation to management, operations,
geographical distribution and the often chaotic schedule of construction stakeholders. As a
result, construction stakeholders and contractors in Cape Town and Paarl were selected as
samples for the research population (Western Cape Province). The samples were selected
by the use of cluster sampling and purposive sampling technique.
Biggam (2008) and Maree and Pieterson (2007) defined cluster sampling as a process of
rearranging a target population into smaller groups (clusters), from which samples are
randomly selected for data collection and result generalisation. Sampling techniques are
important for researchers to decide on the number of respondents from which inference will
be drawn and the techniques to adopt in their selection (sampling method) because of time
and cost constraints (Ganiyu 2016:111). As mentioned earlier, based on the accessibility of
the construction sites and availability of the construction stakeholders, as a result of their
busy schedules, the questionnaires were administered to construction stakeholders and
contractors in Cape Town and Paarl. Thus, the cluster sampling technique was adopted in
the phase of questionnaire administration (quantitative data collection), for an easy and fast
generalisation of findings. For the quantitative data collection, construction and consulting
companies in Cape Town were grouped into clusters of ten (10) in which respondents were
randomly selected using a simple random sampling method. A total of thirty (30) companies
were randomly selected with at least six (6) representatives of each company. Construction
59
and consulting companies in Paarl were grouped into four (4) clusters; fifteen (15)
companies were randomly selected with at least four (4) representatives from each company
as respondents.
To validate the data obtained from the questionnaires, contractors and site supervisors were
interviewed. These participants were selected for interviews using the convenience sampling
method. Participants interviewed had adequate experience in construction, with adequate
years of supervisory responsibilities in the construction sector. The experience of the site
supervisors is arguably a helpful instrument to assess the validity of data obtained from
construction stakeholders. Convenience sampling method, as the name implies, is a quick
and inexpensive approach in research to validate information obtained in the course of a
study (Maree, 2007).
3.7.5 Data collection techniques
Data collection entails the process of exploring a series of data sources to obtain information
for a research study. Nonetheless, Struwig and Stead (2007:80) and Biggam (2015) stated
two types of data collection in a research work: primary and secondary data. A triangulation
data collection technique was adopted for this research; that is, data was not only collected
through questionnaires, but also through interview and literature reviews. Literature reviews,
questionnaires and interviews were used to obtain data for this study as subsets of
secondary and primary data collection.
3.7.5.1 Secondary data collection
Secondary data are easily reached data obtained from research conducted by other
researchers (Struwig & Stead, 2007:80). Further, secondary data can also be referred to as
literature review in research. O’Leary (2010:71) emphasized that it is essential to consult
past innovations for production of new knowledge. Melville and Goddard (2004) noted that
the secondary data (literature review) is obtainable in two different forms: preliminary review
and a comprehensive review of other research works. The preliminary review was adopted
in Chapter One of this study to develop a framework for the study, while the comprehensive
review of literature was conducted in Chapter Two of this study to evaluate and extend the
views of other researcher on comparatively relevant topics. The data obtained from past
research revealed diverse factors affecting the cost of construction and, specifically, the cost
of building materials, as well as a significant number of factors explored from existing
literature to assist in the design of the research questionnaire. Comparatively, most research
was conducted concerning factors affecting cost of building materials, factors affecting the
cost of construction, criteria to be considered in the selection of sustainable building
60
materials, while only an insignificant amount of research has addressed the effects of
increase in the cost of building material on housing delivery. Thus, this research study
poises to consider this lapse. The sources of information for the review of literature included
textbooks, journals, articles, conference proceedings, dissertations and theses.
3.7.5.2 Primary data collection
Leedy and Ormrod (2010) highlighted the most valid information obtained in a research to be
primary data. This method of data collection involves researchers making certain that the
questions are designed for respondents in a clear and understandable manner to elicit
thorough and fitting information (Kumar, 2011). The primary data for the study were collected
through the administration of quantitative questionnaires to survey respondents as well as
through interviews conducted face-to-face with site supervisors, while the questionnaires
were administered to respondents by hand and via the internet (survey monkey).
3.7.5.2.1 Interview
This method of data collection is qualitative in nature and commonly open ended. However,
Flick (2015) is of opinion that when conducting that qualitative interview there should be a
dialogue between interviewer and interviewee. According to Leedy and Ormrod, (2010)
interviews in a survey are designed in two forms: structured and semi-structured, depending
on the purpose of the survey.
For the purpose of this study, a semi-structured qualitative interview was chosen, due to the
advantage of the flexibility of semi-structured interviews. In agreement, Kumar (2011:160)
stressed that interviews provide the researcher a level of spontaneity, flexibility and liberty to
dialogue and interact with the survey respondents.
The respondents were informed prior to the meeting of the focus of the interview and the
relevance of the research study, giving respondents sufficient time to prepare in advance.
The interview was tape-recorded with permission from the respondents. A total of three (3)
construction sites were selected for data validation (interview).
An interview was conducted with a site supervisor on each construction site selected for data
validation, as site supervisors are in the most suitable position to disclose the factors that
cause increases in the cost of building materials. Arguably, site supervisors have significant
knowledge of the factors affecting the cost of building materials on construction projects.
61
3.7.5.2.2 Questionnaire design
The most essential aspect of any survey is the questionnaire design (Kumar, 2011). The
research questionnaire, designed with close-ended questions, is designed in consonance
with the study objectives as well as the information derived from reviewed literature.
The questionnaire was structured in sections, where each section addresses a particular
objective. Table 3.4 illustrates the relationship between various sections and study
objectives. The first section of the questionnaire inquires of the biographical information of
the survey participants. The second section comprises four sub-sections, and addresses the
first objective of the research with the aim of identifying the factors responsible for the
increase in the cost of building materials. This section considers economic related factors,
building production processes related factors, stakeholder related factors and external
factors. The third section of the questionnaire identifies effects of increase in the cost of
building on housing delivery. The final and fourth section is comprised of four sub-sections,
which address the final objective of the study, with the aim of ascertaining the criteria to be
considered in the selection of building materials for affordable housing. The sub-sections
considered the influence of stakeholders on materials selection, guidelines for materials
selection, criteria to be considered during materials selection and project factors affecting the
types of materials to be selected.
Table 3.4: Questionnaire design
Section Section title Section objective
1 Biographical information
2 Factors responsible for increase in cost of building materials Objective 1
3 Effects of increase in the cost of building materials on
housing delivery
Objective 2
4 Criteria for selection of sustainable building materials Objective 3
3.7.6 Data analysis for the study
Data analysis includes tabulating, data testing, categorising and examining results to
address the purpose of a study (Yin, 2003). The quantitative and qualitative data gathered
were analysed using the Statistical Package for Social Sciences (SPSS) software. The
quantitative data, obtained by questionnaires, were analysed with descriptive statistics.
Conversely, the qualitative data were analysed technically by content analysis.
62
3.7.6.1 Descriptive statistics
Descriptive statistical analysis in research can be defined as the process of showing or
briefing a set of quantitative data in clear formats (tables and charts, for example)
(Quartaroli, 2009). Struwig and Stead (2007:158) posited that the purpose of using a
statistical tool in data analysis is to show a direct picture of a large amount of data. Henn et
al. (2006) and Leedy and Ormrod (2010) highlighted the three predominate terms used in
descriptive statistical data analysis as central tendency measurement, dispersion
measurements and frequency distributions. Thus, this study adopted the use of frequency
distribution and central tendency measurement technique (mean and standard deviations) in
analysing the quantitative data obtained in the survey.
3.7.6.2 Content analysis
Content analysis principally involves the coding and transcribing of human communication
(written or oral) or other means of communication: videotapes and Internet blogs (Babbie,
2007; Leedy & Ormrod, 2010). Furthermore, Flick, (2015) added that this approach includes
the summary of content, while irrelevant words are omitted. Notably, content analysis is an
effective method for answering a large research questions. When compared with analysis of
questionnaires, content analysis consumes more time in terms of data processing and
transcribing (Thomas, 2003:60). The content analysis adopts the inductive approach in
exploring the advantages and disadvantages of a text or statement in order to oppose or
support a theory. In context, this study reported a summary of the relevant contents in the
transcribed data obtained from the interviewees, while less important information was
omitted in the reporting process.
3.8 Validity and reliability of the data
Validity and reliability of the research tool impact the authenticity of the research work.
Struwig and Stead (2007) stressed that the validity of a research tool signifies the degree to
which the tool measures the reason for which is was designed, while reliability makes sure
there is consistency in findings whenever it is constantly used. Notably, the principles validity
and reliability differ depending on the nature of the research conducted.
3.8.1 Validity
The validity of a research refers to the originality of the survey tool, hence, the research
findings (Struwig & Stead, 2007:159). Leedy and Ormrod (2010) otherwise stated that the
validity of a research is the extent to which the instrument used measures what it is
63
supposed to measure. Validity refers to the credibility of research findings (Struwig & Stead,
2007:159).
3.8.2 Reliability
Research reliability refers to the stability of a research result when used at different times or
administered to different subjects from the same population (Leedy & Ormrod, 2010). The
main reason for conducting reliability of a test is to reduce the inaccuracies and preferences
in a survey (Yin, 2003). The Cronbach’s Alpha test is one such statistical tool frequently
used for assessing the reliability of data (Girden & Kabacoff, 2011). Thus, in the context of
this study, the reliability of the questionnaire was assured by testing the questionnaire using
the Cronbach's coefficient alpha. It was noted that the closer the coefficient is to 1, the more
reliable the survey instrument is, with the optimal Cronbach's coefficient alpha value above
0.7.
3.9 Chapter summary
This chapter provided a comprehensive overview of the research methodology adopted in
this study. A mixed research method (quantitative and qualitative) was adopted to achieve
the aim and objectives of the research. The quantitative research questionnaire was
structured and designed to elicit the perceptions of construction professionals and
stakeholders on the effects of increase in the cost of building material on sustainable
housing delivery in the Western Cape. Literature reviews, interviews and questionnaires
were used in collecting both primary and secondary data for the study. The approaches used
for questionnaire administration were both ‘online’ and ‘hand-in’ approaches. Thereafter, the
reliability of the findings and results were tested using the Cronbach’s alpha coefficient
reliability test.
64
EXPLORATORY STUDY
Pilot open -ended studyUnstructured preliminary
interview
MAIN STUDY
Closed -ended questions(Construction Stakeholders)
Validation processSemi-structured interview
(Construction Stakeholders)
Descriptive StatisticsContent Analysis
Discussion, conclusion and recommendation
Figure 3.2: Research methodology
65
CHAPTER FOUR
DATA ANALYSIS AND DISCUSSION OF FINDINGS
4.1 Introduction
This chapter presents the results of a quantitative data analysis conducted using descriptive
statistical techniques. Additionally, detailed accounts of participant responses during the
qualitative interviews were reported and tabulated under appropriate sections. The results of
statistical analysis were interpreted: inferences were drawn from the results and discussed
thoroughly to bring the research conclusions into focus.
4.2 Exploratory study
The exploratory study was conducted in Cape Town, in the Western Province of South
Africa. The study was conducted to identify the factors responsible for the increase in the
cost of building materials, its effects on the delivery of affordable housing and criteria to be
considered in the selection of building materials for sustainable housing delivery. The
exploratory study was also conducted to ascertain questionnaire clarity for the main study in
the industry. The study population was comprised of architects, site engineers, project
managers, quantity surveyors, contractors and government workers. The population
sampling technique adopted for the exploratory study was the ‘simple random sampling
method’. A total of twenty (20) questionnaires were administered. The respondents were
requested to complete the questionnaire and make constructive comments where
necessary. Successively, comments and further input from the respondents were considered
and suitable modifications were made in the questionnaire design for the main study.
4.3 Questionnaire survey for the main study
Quantitative data collection for this study was conducted through the use of a questionnaire
survey. A total of two hundred and twenty-five (225) questionnaires were administered to
construction stakeholders (architects, site engineers, project managers, quantity surveyors,
contractors, building materials suppliers, site managers and government workers) in the
Western Cape Province of South Africa. One hundred and thirty-seven (137) questionnaires
were administered in person to selected respondents, of which fifty-one (51) questionnaires
were adequately completed and retrieved. Subsequently, eighty-eight (88) were
66
administered online via electronic mails: eighteen (18) questionnaires were completed and
sent back electronically. Ultimately, then, sixty-nine (69) questionnaires were retrieved and
used for analysis.
4.4. Biographical information of respondents
4.4.1 Participants’ companies
The results in Figure 4.1 present the characteristics of the respondents from different work
divisions, professions and companies. The information obtained was from both the private
and public sector of the construction industry, with 13% of the respondents from project
management firms; 29% of respondents from contracting firms; 10.1% from material
suppliers; 21.7% from construction management firms; 11.6% from government
establishments; 7.2% from quantity surveying firms; and 7.2% from architectural firms. From
this result, it is evident that the majority of respondents undertook housing construction, an
indication that the data provided by the respondents in their survey response could be relied
upon for making decisions pertaining to sustainable housing construction.
Figure 4.1: Participants’ companies
4.4.2 Respondents’ gender
Table 4.1 shows that the majority (84%) of survey participants are male, while female
participants represent the only 16%. This gender distribution indicates that male participants
67
are significantly higher in number than their female counterparts. Nevertheless, this
inference doesn’t suggest that the female participation is not significantly reliable for this
research study. In fact, these results proved that the respondents were qualified; inference
suggests that equality of the gender is significantly consistent for this research study.
Table 4.1: Respondents’ gender
Category
Frequency Percentage
Male
58 84.1
Female
11 15.9
Total
69 100
4.4.3 Age group
Figure 4.2 presents the age groups of survey respondents. It was found that 11.6% of the
respondents were below the age of twenty-six. The age group between twenty six to thirty
years was made up of 23.2% of study participants The highest percentage of respondents
fell between the ages of thirty-one and thirty-five, representing 31.9% of the total
respondents. The age group between thirty-six to fourty made up 14.5% of study
participants. The age group between fifty-one to fifty-five years made up 4.3% of study
participants. Respondents falling between age fourty-six and fifty represent of 11.6% of
survey respondents. The table indicates that 97.1% of survey respondents were not older
than sixty-five years of age, while a mere 2.9% respondents were above sixty-five years of
age, suggesting that the majority of survey respondents were middle age. Analysis on
respondents’ age group showed that an overwhelming 97.1% were not older than sixty-five
years of age, while only 2.9% respondents were above sixty-five years, proving that the
respondents were qualified, competent and with certain and valid expertise on sustainable
building projects and construction in general.
68
Figure 4.2: Respondents’ age group
4.4.4 Highest formal qualifications
Figure 4.3 presents the formal qualifications obtained by the study participants. Respondents
having diploma certificates as the highest formal educational qualification represented 58%.
Respondents holding Post Graduate diplomas and Bachelor’s degrees represented 38%. A
minority of respondents (4%) hold Master’s degrees in their various fields. Figure 4.3 reveals
that highest formal educational qualification (at 58%) that survey respondents held was a
Diploma Certificate. The results of analysis on respondent demographic and educational
background information indicate that respondents were adequately knowledgeable
practitioners in the construction industry, whose judgments on issues of construction project
delivery can be relied on.
Figure 4.3: Highest formal qualifications
69
4.4.5 Position of respondents
Figure 4.4 presents the positions held by survey participants. The largest groups of the
respondents (20.3%) were project managers, followed by quantity surveyors which
represented 17.4%; and site managers at 11.6%; construction managers at 13%; 11.6%
were sales consultants; contractors at 7.2%, site managers at 5.8%; and architects at 13%.
The outlook of results in Figure 4.4 shows that the geographical spread of the respondents
within the building construction industry can be declared nearly perfect even and thus serve
as reliable data. Similarly, the opinions of various stakeholders in the construction will
enhance the result reliability.
Figure 4.4: Position of the respondents
4.4.6 Numbers of years in the present position
Figure 4.5 presents that 7% of the respondents had been in their current position below one
year; 23% had been working in the position for one to five years; 42% had been in the
position for six to ten years; 18% had been in their position for eleven to fifteen years; 7%
had been in the current position for sixteen to twenty years; and 3% had been in their current
position above twenty years. The results of analysis on respondent demographics revealed
that of respondents sampled, 93% has been in their current position for more than five years,
indicated that the respondents were thoroughly qualified, having gained much experience
from their present and previous firms in construction industry.
70
Figure 4.5: Years in present position
4.4.7 Experience of respondents
Table 4.2, presents the work experience of respondents in the construction sector, reveals
respondents with one to five years’ work experience in the construction industry represented
7.2% of the total respondents. Respondents having six to ten years construction work
experience represented 10.1% of the total. A substantial 36.2% of study participants had
been involved in construction work for eleven to fifteen years, while 21.7% had sixteen to
twenty years’ experience, and 24.6% had construction experience of greater than twenty
years. Also from Table 4.2, the working experience of the minority of respondents (17%) in
the construction industry spanned between one to ten years, while 58% of respondents had
been working in the construction sector for more than ten years. The years of experience of
respondents are significantly worthy to achieve the purpose of the study, as a significant
83% of study respondents have more than ten years work experience in the construction
industry. Nonetheless, this is not to suggest that the input and work experiences of the
respondents working only between 1-5 years is not significantly reliable for this research.
Table 4.2: Experience of respondents in the construction industry
Category Frequency Percentage
1 - 5 years 5 7.2
6 - 10 years 7 10.1
11- 15 years 25 36.2
16-20 years 15 21.7
20 years above 17 24.6
Total 69 100
71
4.5 Testing the reliability of the research Instrument
The reliability of the questions used in the study was tested with the Cronbach’s alpha test
using a Statistical Package for Social Sciences (SPSS) version 24, as this ensures reliability
of research questions. Cronbach’s alpha reliability test is an estimate of the internal
consistency associated with the scores that can be derived from a scale or composite score
(Tavakol & Dennick, 2011:53). Data in Table 4.3 shows that the Cronbach’s alpha coefficient
values are greater than 0.70 (>0.70), and Tavakol and Dennick (2011:53) endorsed that the
score values between 0.70-0.95 are standardized values for the reliability of a test to be
secured.
Table 4.3 Reliability of research instrument
Question
numbers
Headings Number
of the
items
Cronbach’s
alpha
coefficient
value
Section B1 Economic related factors responsible for increase in the cost
of building materials
10 0.7
Section B2 Building production process related factors responsible for
increase in the cost of building materials
22 0.7
Section B3 Stakeholder related factors responsible for increase in the
cost of building materials
7 0.7
Section B4 External factors related factors responsible for increase in the
cost of building materials
10 0.8
Section C Effects of increase in the cost of building materials on
housing delivery
23 0.9
Section D1 Influence of stakeholder in selection of building materials 9 0.7
Section D2 Guidelines to materials selection in construction towards
enhancing sustainable building delivery
10 0.8
Section D3 Criteria often considered during materials selection for
optimum materials usage in relation to sustainability
categories
29 0.8
Section D4 Project factors affecting materials selection 10 0.8
All questions used 131 0.9
4.6 Presentation of findings
The study is designed to identify effects of significant factors affecting building materials
cost on housing delivery towards sustainability in South Africa. From the findings, the
significant factors affecting the cost of building materials, its effects in the delivery of
sustainable housing and criteria often considered in the selection of building materials are
presented.
72
4.6.1 Economic related factors responsible for increase in cost of building materials
Table 4.4 presents the perceptions of survey respondents in the order of severity of
economic related factors affecting the cost of building materials. Respondents were
requested to indicate the extent to which each of the identified factors affected the cost of
building materials, following a four (4) point Likert scale: 4=Strongly agree, 3=Agree,
2=Disagree and 1=Strongly disagree. In Table 4.4, inflation, with a mean value of 3.55, was
identified as the most significant economic related factor affecting the cost of building
materials. A high 94.2% of respondents strongly agreed that this factor affects the cost of
building materials, whereas a minority (5.8%) of respondents disagreed, indicating that does
not affect the cost of building materials. However, it can be inferred that this factor is widely
regarded as a major contributor to the increase in cost of building materials. Overwhelming
number of respondents 97.1% agreed that exchange rate of Rand (mv=3.53) was a notable
factor affecting cost of building materials. Thus, this factor maintained a slightly closer mean
value as inflation, while 2.8% of the respondents disagreed that this factor was significant.
Another large percentage (92.8%) of respondents agreed that interest rate (mv=3.38) is an
important factor affecting cost of building materials, and 88.4% of respondents perceived
that cost of building materials (mv=3.33) as a notable economic related factor responsible for
increase in the cost of building materials (Table 4.4).
Table 4.4 Economic related factors
Economic related
factors
No.
Str
on
gly
ag
ree
(%)
Ag
ree
(%)
Dis
ag
ree
(%)
Str
on
gly
dis
ag
ree
(%))
Me
an
va
lue
(mv
)
Std
.D
Ran
k (
r)
Inflation 69 60.9 33.3 5.9 0.0 3.55 0.61 1
Exchange rate of Rand 69 56.5 40.6 1.4 1.4 3.52 0.60 2
Interest rate 69 44.9 47.9 7.2 0.0 3.38 0.62 3
Cost of building
materials
69 44.9 43.5 11.6 0.0 3.33 0.68 4
Market condition 69 44.9 36.2 18.8 0.0 3.26 0.76 5
Fluctuation in the cost
of raw materials
69 36.2 50.7 13.0 0.0 3.23 0.67 6
Local taxes 69 34.8 46.4 14.5 4.3 3.12 0.81 7
Supply and demand of
building materials
69 31.9 44.9 21.7 1.4 3.07 0.77 8
Inadequate production
of building materials
69 27.5 39.1 31.9 1.4 2.93 0.81 9
Scarcity of building
materials
69 21.7 52.2 21.7 4.3 2.91 0.78 10
73
4.6.2 Building production related factors responsible for the increase in cost of
building materials
Table 4.5 presents the perception of the respondents on building production related factors
responsible for increase in the cost of building materials towards enhancing sustainable
housing delivery. The respondents were required to use a four (4) point Likert scale:
1=Strongly disagree, 2=Disagree, 3=Agree, 4=Strongly disagree. The findings from the table
shows that wastages of building materials by workers (mv=3.31) and poor site planning
preventing easy movement of materials (mv=3.15) are significant site related factors
responsible for increase in the cost of building materials. While cost of transportation and
distribution of labour (mv=3.28), cost of power supply (mv=3.24) and cost of labour
(mv=3.17) were identified as top human related factors. The table also shows that design
changes (mv=3.36), additional work due to change in design (mv=3.29) and wrong method
of estimation by quantity surveyor (mv=3.24) as design related factors responsible for
increase in the cost of building materials towards sustainable housing delivery.
74
Table 4.5: Building production related factors responsible for increase in cost of building
materials
Building production related factors
No.
Str
on
gly
ag
ree
(%
)
Ag
ree
(%)
Dis
ag
ree
(%)
Str
on
gly
dis
ag
ree
Me
an
va
lue
(mv
)
Std
.D
Ra
nk
(r)
Site related factors
Wastages of building materials by labourers
69 40.6 50.7 8.7 0.0 3.31 0.63 1
Poor site planning prevent easy movement of materials
69 52.2 20.3 18.8 8.7 3.15 1.02 2
Inadequate infrastructural facilities
69 18.8 65.2 15.9 0.0 3.03 0.59 3
Unsuitable location for building materials storage
69 27.5 47.8 21.8 2.9 3.00 0.79 4
Cost of fuel 69 29.0 46.4 18.8 5.8 2.94 0.85 5
Pilferage of materials on site
69 18.8 56.5 24.6 0.0 2.94 0.66 6
Shortage of building materials on site
69 20.3 49.3 24.6 5.8 2.84 0.82 7
Human related factors
Cost of transportation and distribution of labour
69 40.6 46.4 13.0 0.0 3.28 0.68 1
Cost of power supply 69 43.5 39.1 15.9 1.4 3.24 0.77 2
Cost of labour 69 44.9 33.3 15.9 5.8 3.17 0.91 3
Cost of plant 69 31.9 52.2 13.2 2.9 3.13 0.74 4
Communication problem between labourer and supervisors
69 34.4 39.1 24.6 1.4 3.07 0.81 5
Cost of fuel 69 31.9 39.1 21.7 7.2 2.96 0.91 6
Lack of discipline among labourers
69 24.6 40.6 26.1 8.7 2.81 0.91 7
Delay in the payment of construction labourers
69 15.9 42.0 29.0 13.0 2.81 0.91 8
Design related factors
Design changes 69 37.7 49.9 11.6 1.4 3.36 0.75 1
Additional work due to change in design
69 37.7 55.1 5.8 1.4 3.29 0.64 2
Wrong method of estimation by quantity surveyor
69 42.0 43.5 11.6 2.6 3.24 0.77 3
Construction design complexity
69 43.3 42.0 10.1 4.3 3.24 0.71 4
Additional work due to errors
69 37.7 49.3 11.6 1.4 3.23 0.79 5
Design team experience 69 39.1 39.1 20.3 1.4 3.16 0.79 6
Inadequate coordination among design team
69 26.1 59.4 14.5 0.0 3.12 0.63 7
4.6.3 Stakeholder related factors responsible for increase in cost of building materials
Table 4.6 presents findings on stakeholder related factors responsible for increase in the
cost of building materials. The respondents were required to use a four (4) point Likert scale:
75
1=Strongly disagree, 2=Disagree, 3=Agree, 4=Strongly disagree. The majority of the
respondents (89.9%) agreed on client contribution to design change (mv=3.28) as a top
stakeholder related factor responsible for increase in the cost of building materials. Most of
the respondents (92.8%) indicated that incorrect construction method (mv=3.19) was also a
notable factor responsible for increase in the cost of building. Improper planning (mv=3.17),
client demand on high quality project delivery (mv=3.16), and supplier default (mv=3.14)
were also identified as contributory factors to an increase in cost building materials.
Table 4.6: Stakeholder related factors responsible for increase in the cost of building materials
Stakeholder related factors No. S
tro
ng
ly
ag
ree
(%
)
Ag
ree
(%
)
Dis
ag
ree
(%)
Str
on
gly
dis
ag
ree
(%)
Me
an
va
lue
(m
v)
Std
.D
Ra
nk
(r)
Client contribution to design change
69 37.7 52.2 10.1 0.0 3.28 0.63 1
Incorrect construction method 69 29.0 63.8 4.3 2.9 3.19 0.64 2
Improper planning 69 39.1 42.0 15.9 2.9 3.17 0.80 3
Client demand on high quality project delivery
69 39.1 42.0 15.9 2.9 3.16 0.72 4
Supplier default 69 34.8 49.3 11.6 4.3 3.14 0.79 5
Delay in the supply of materials on site
69 21.7 52.2 11.6 8.7 3.09 0.87 6
Fraudulent activities 69 21.7 52.2 23.2 2.9 2.92 0.75 7
Contractor issue (change initiated by contractor to improve quality )
69 23.3 43.5 26.1 7.2 2.82 0.87 8
4.6.4 External factors responsible for increase in the cost of building materials
Table 4.7 presents external factors responsible for increase in the cost of building materials.
The respondents were required to use a four (4) point Likert scale: 1=Strongly disagree,
2=Disagree, 3=Agree, 4=Strongly disagree. Increase in cost of hiring construction
machineries (mv=3.02) emerged as the highest rated external factor responsible for increase
in the cost of building materials. A high percentage (82.6%) of respondents agreed that this
factor significantly affected cost of building material, while 17.4% of respondents disagreed
that increase in cost of hiring construction machineries affected the cost of building
materials. Government legislation (mv=3.01) and change in government policies and
regulations (mv=3.00) were seen as notable external factors, as indicated by respondents in
Table 4.7.
76
Table 4.7: External factors responsible for increase in the cost of building materials
External factors No.
Str
on
gly
ag
ree
(%
)
Ag
ree
(%
)
Dis
ag
ree
(%)
Str
on
gly
dis
ag
ree
(%)
Me
an
va
lue
(m
v)
Std
.D
Ra
nk
(r)
Change in government policies and regulation
69 21.7 60.9 15.9 1.4 3.02 0.66 1
Government legislations 69 18.8 66.7 11.6 2.9 3.01 0.65 2
Lack of substitute for product 69 23.2 55.1 17.4 4.3 3.00 0.76 3
Level of advanced technology 69 23.2 53.6 18.8 4.3 2.95 0.77 4
Increase in cost of hiring construction machineries
69 21.7 52.2 24.6 1.4 2.94 0.73 5
Poor nature of construction site
69 21.7 56.5 14.5 7.2 2.92 0.81 6
Weather condition 69 26.1 44.9 23.2 5.8 2.91 0.85 7
Effect of rainfall on building materials
69 20.3 50.7 23.2 5.8 2.85 0.81 8
Political interference 69 17.4 53.6 20.3 8.7 2.80 0.83 9
Force majeure (natural occurrences)
69 17.4 47.8 30.4 4.3 2.78 0.78 10
4.6.5 Effects of increase in the cost of building materials on housing delivery
Table 4.8 presents effects of increase in the cost of building materials on housing delivery.
Respondents were required to indicate the extent to which each of the identified factors has
an effect on housing delivery using a four (4) point Likert scale with values as follows: 4=to
a very large extent, 3=to a large extent, 2=to a little extent, 1=not at all. A significant 89.9%
of respondents indicated fluctuation in cost of construction (mv=3.26) was ranked as top
most significant effect of increase in the cost of building materials on delivery of affordable
housing. High maintenance costs due to poor workmanship (mv=3.23) emerged as the
second critical factor affecting housing delivery, while 84.1% of the respondents indicated
that increase in the cost of repair due to inferior materials used (mv=3.19) has a significant
effect on delivery affordable housing. Poor workmanship (mv=3.14) and client expectation
on quality project delivery (mv=3.11) were identified to have a large extent on the delivery of
affordable housing. Building collapses due to the use of poorer quality materials (mv=3.10),
conflict between client and contractor due to upward review of contract sum (mv=3.10),
delay on the progress of project works (mv=3.10) were indicated as a notable effects on
housing delivery. All maintained the same mean value, although less significant than one
another, considering the standard deviation of the three factors.
77
Table 4.8: Effects of increase in the cost of building materials on housing delivery
Effects No.
To
a v
ery
larg
e
ex
ten
t (%
)
To
a l
arg
e
ex
ten
t (%
)
To
a l
ittl
e
ex
ten
t (%
)
No
t a
t a
ll
(%)
Me
an
va
lue
(m
v)
Std
.D
Ra
nk
(r)
Fluctuation in cost of construction 69 37.7 52.2 8.7 1.4 3.26 0.68 1
High maintenance cost due to poor workmanship
69 36.2 50.7 13.0 0.0 3.23 0.67 2
Increase in the cost of repair due to inferior materials used
69 31.9 56.5 10.1 1.4 3.19 0.67 3
Poor workmanship 69 31.9 52.2 14.5 1.4 3.14 0.71 4
Affect client expectation’s on quality project delivery
69 33.3 46.4 18.8 1.4 3.11 0.75 5
Building collapses due to the use of less quality materials
69 34.8 43.5 18.8 2.9 3.10 0.80 6
Conflict between client and contractors due to upward review of contract sum
69 34.8 44.9 15.9 4.3 3.10 0.82 7
Delay on the progress of project works
69 26.1 60.9 10.1 2.9 3.10 0.69 8
Poor quality of construction product 69 21.7 65.2 13.0 0.0 3.09 0.58 9
Increase in final cost of building products, that is final cost of production higher than budgeted
69 31.9 47.8 15.9 4.3 3.07 0.81 10
High rate of contractors’ fraudulent practices
69 27.5 53.6 17.4 1.4 3.07 0.71 11
Low income earners are priced out for home ownership due to high cost of building
69 31.9 49.3 11.6 7.2 3.06 0.86 12
Affect the aesthetics value of building product
69 20.3 65.2 13.0 1.4 3.04 0.63 13
Shortage in the delivery of housing to the populace
69 29.0 50.7 15.9 4.3 3.04 0.79 14
Affect gross domestic product (GDP) contribution to the economy
69 21.7 62.3 13.0 2.9 3.03 0.68 15
Investment return on construction project are delayed
69 27.5 52.2 15.9 4.3 3.02 0.79 16
Threatening health and safety of workers on site
69 27.5 49.3 20.3 2.9 3.01 0.77 17
Completion at the expense of other projects
69 23.2 50.7 24.6 1.4 2.96 0.74 18
Low volume of construction product 69 17.9 60.9 20.3 1.4 2.94 0.66 19
Transportation cost – e.g. returning substandard materials to the supplier
69 26.1 50.7 14.5 8.7 2.94 0.87 20
Increase in project abandonment 69 21.7 47.8 27.5 2.9 2.88 0.78 21
Hindered adequate implementation of innovation in construction
69 17.4 60.9 20.3 1.4 2.87 0.62 22
Unemployment of construction workers
69 23.2 33.3 37.7 5.8 2.74 0.89 23
78
4.6.6 Influence of stakeholders in materials selection
Table 4.9 provides a summary of the results of respondents. Respondents were asked to
rank the level of involvement of relevant stakeholders on a four (4) point Likert scale:
4=Higher, 3=High, 2=Low and 1=Very low as involved in the influencing of materials
selection. Client (mv=3.43) has the highest degree of involvement while none of respondents
indicated that client has a low degree involvement influencing materials selection. Architect
and designer (mv=3.40) and technical consultant (mv=3.10) were identified by the
respondents as having a high influence in the materials selection.
Table 4.9: Influence of stakeholders in materials selection
Stakeholders No.
Ve
ry H
igh
(%)
Hig
h (
%)
Lo
w (
%)
Ve
ry L
ow
(%)
Me
an
va
lue
(mv
)
Std
.D
Ran
k (
r)
Client 69 55.1 33.3 11.6 0.0 3.43 0.69 1
Architect and designer 69 59.4 29.0 4.3 7.2 3.40 0.88 2
Technical consultant 69 33.3 57.7 8.7 7.2 3.10 0.84 3
Project manager 69 30.4 30.4 23.2 15.9 2.75 1.06 4
Quantity surveyor 69 29.0 30.4 27.5 13.0 2.75 1.09 5
Suppliers of materials 69 29.0 29.0 23.2 18.8 2.68 1.09 6
Materials manufacturer 69 26.1 26.1 27.5 20.5 2.58 1.09 7
Contractors 69 23.2 30.4 27.5 18.8 2.57 1.05 8
Site manager 69 11.6 34.4 34.4 18.8 2.39 0.93 9
4.6.7 Guidelines to materials selection in construction towards enhancing sustainable
housing delivery
Table 4.9 presents the important of definite guidelines to materials selection in construction
towards enhancing sustainable housing delivery. These guidelines were evaluated by the
respondents based on a four (4) point Likert scale: 4=Extremely important, 3=Important,
2=Less important and 1=Not important. A significant percentage (86.3%) of the respondents
agreed building design (mv=3.36) is important in enhancing sustainable housing delivery in
construction. Most of the respondents (86.6%) also agreed that in selecting sustainable
building materials, it is imperative to consider the environmental impact of the materials
79
(mv=3.35). Material life cost (mv=3.23) was identified by the respondents as another key
guideline to material selection for enhancing sustainable housing delivery. Moreover,
material functional demands, material market trend demands and technological impact of
materials were considered as important guidelines to material selection and were
consequently ranked based on the mean value of 3.20, 3.12 and 3.11, respectively.
Table 4.10: Guidelines to materials selection in construction towards enhancing sustainable
building delivery
Guidelines No.
Ve
ry i
mp
ort
an
t
(%)
Im
po
rta
nt
(%)
Le
ss
Im
po
rta
nt
(%)
No
t im
po
rta
nt
(%)
Me
an
va
lue
(mv
)
Std
.D
Ra
nk
(r)
Building design 69 42.8 43.5 5.8 2.9 3.36 0.73
1
Environmental impact of materials 69 47.8 39.1 11.6 1.4 3.33 0.74 2
Material life cycle cost 69 33.3 56.5 10.1 0.0 3.23 0.62 3
Material functional demands 69 33.3 53.6 13.0 0.0 3.20 0.65 4
Material market trend demands 69 24.6 62.3 13.00 0.0 3.12 0.61 5
Technological impact of materials 69 29.0 53.6 17.6 0.0 3.11 0.68 6
Material structural demands 69 24.6 60.9 14.5 0.0 3.10 0.63 7
Material efficiency (use of renewable and recyclable materials)
69 29.0 47.8 17.4 5.8 3.00 0.84 8
Socio economic impact of materials 69 34.8 29.0 30.4 5.8 2.93 0.94 9
Material overview 69 18.8 47.8 33.3 0.0 2.86 0.71 10
4.6.8 Sustainable criteria for building materials selection
Table 4.11 shows the ranking results for each criteria category (e.g. socio economic,
environmental and technological). Respondents were asked to rate the level of importance
of the derived criteria based on a four (4) point Likert scale: 4=Extremely important,
3=Important, 2=Less important, and 1=Not important. Maintenance cost was ranked as the
first priority in the socio economic category, with a mean value of 3.36. Energy consumption
(mv=3.34) was also ranked as having major significance under the environmental category,
while maintainability (mv=3.43) had the highest ranking in the technical category and
interestingly was the highest among all the selection criteria. According to Table 4.11, a total
of 12 critical criteria, consisting of four environmental criteria, four technical criteria, and four
80
socio economic criteria, were recorded to have high levels of importance for evaluating
building materials. These twelve criteria are ‘maintainability’ (T1), ‘life expectancy’ (T2),
‘maintenance cost’ (S1), ‘energy consumption’ (E1), ‘health and safety’ (S2), ‘fire resistance’
(T3), ‘initial cost’ (S3), ‘disposal cost’ (S4), ‘minimise pollution’ (E2), ‘resistance to decay’
(T4), ‘air quality’ (E3), and ‘low or non-toxicity’ (E4) with the following mean values of 3.43,
3.41, 3.36, 3.34, 3.34, 3.30, 3.29, 3.26, 3.23, 3.23, 3.22, and 3.21, respectively.
Table 4.11: Sustainable criteria for building materials selection
Criteria No. E
xtr
em
ely
imp
ort
an
t
(%)
Imp
ort
an
t
(%)
No
t
imp
ort
an
t
(%)
Le
ss
imp
ort
an
t
(%)
Me
an
va
lue
(mv
)
Std
.D
Ra
nk
(r)
Socio- Economic criteria
Maintenance cost 69 42.0 52.2 5.8 0.0 3.36 059 1
Health and safety 69 49.3 39.1 8.7 2.9 3.34 0.76 2
Initial cost 69 44.9 39.1 15.9 0.0 3.29 0.73 3
Disposal cost 69 34.8 56.5 8.7 0.0 3.26 0.61 4
Aesthetics 69 29.0 52.2 18.8 0.0 3.10 0.68 5
Labour availability 69 36.2 37.7 18.8 7.2 3.02 0.92 6
Recycle cost 69 29.0 42.0 21.7 7.2 2.93 0.89 7
Use of local materials 69 20.3 49.3 23.2 7.2 2.83 0.84 8
Transportation cost 69 20.3 36.2 40.6 2.9 2.74 0.82 9
Environment criteria
Energy consumption 69 52.2 30.4 17.4 0.0 3.34 0.76 1
Environmental pollution 69 39.1 44.9 15.9 0.0 3.23 0.71 2
Air quality 69 42.0 39.1 17.4 1.4 3.22 0.76 3
Low or non-toxicity 69 43.5 36.1 18.8 1.4 3.21 0.80 4
Sound disposal options 69 34.8 44.9 18.8 1.4 3.13 0.77 5
Embodied energy in the material
69 34.8 43.5 21.7 0.0 3.13 0.75 6
Environmental statutory compliance
69 31.9 46.4 21.7 0.0 3.10 0.73 7
Green gas emission 69 29.0 50.7 20.3 0.0 3.08 0.70 8
Amount of likely wastage in the use of materials
69 27.5 53..6 17.4 1.4 3.07 0.71 9
Ozone depletion potential 69 27.5 47.8 20.3 4.3 2.99 0.81 10
Potential for recycling as well as re-use
69 24.6 43.5 27.5 4.3 2.88 0.83 11
Technical criteria
Maintainability 69 49.3 44.9 5.5 0.0 3.43 0.61 1
Life expectancy of materials (strength, durability)
69 58.0 27.5 11.6 2.9 3.41 0.81 2
Fire resistance 69 42.0 46.4 11.6 0.0 3.30 0.67 3
Resistance to decay 69 37.7 49.3 11.6 1.4 3.23 0.71 4
Energy saving and thermal insulation
69 46.4 29.0 23.2 1.4 3.20 0.71 5
Moisture resistance 69 39.1 40.6 17.4 2.9 3.16 0.82 6
Ease of construction 69 33.3 49.3 17.4 0.0 3.15 0.70 7
Material availability 69 29.0 59.4 8.7 2.9 3.14 0.69 8
Sound insulation 69 21.7 62.3 15.9 0.0 3.06 0.62 9
81
4.6.9 Project factors
Table 4.11 presents the perception of the respondents on the project factors determining the
nature and type of materials to be selected. Respondents were requested to indicate the
extent to which each of the identified project factors affect the nature and type of materials to
be selected, using a four (4) point Likert scale with values as follows: 4=To a very large
extent, 3=To a large extent, 2=To a little extent, 1=Not at all. The majority (94.2%) of
respondents indicated that client preference (mv=3.55) is an important factor in determining
the nature and type of materials to be selected. However, a minority of respondents (4.3%)
indicated that this has little impact in the selection of building materials, and 1.4% indicated
that it actually has no impact at all. Complexity of project and budgeted project cost, with
mean values of 3.40 and 3.30 respectively, were rated by respondents as having a large
impact in the selection building materials.
Table 4.12: Project factors
Factors No.
To
a v
ery
larg
e
ex
ten
t (%
)
To
a l
arg
e
ex
ten
t (%
)
To
a l
ittl
e
ex
ten
t (%
)
No
t a
t a
ll
(%)
Me
an
va
lue
(m
v)
Std
.D
Ran
k (
r)
Client preference 69 62.3 31.9 4.3 1.4 3.55 0.65 1
Complexity of project 69 49.3 42.0 8.7 0.0 3.40 0.64 2
Budgeted project cost 69 43.5 43.5 13.0 0.0 3.30 0.69 3
Scope of project 69 37.7 52.2 7.2 2.9 3.25 0.72 4
Stakeholder expectation 69 37.7 49.3 13.0 0.0 3.24 0.67 5
Project schedule 69 37.7 50.7 8.7 2.9 3.23 0.73 6
Size of project 69 40.6 44.9 10.1 4.3 3.21 0.80 7
Site condition 69 33.3 50.7 15.9 0.0 3.17 0.69 8
Nature of the project 69 24.6 65.2 10.1 0.0 3.14 0.58 9
Type of project 69 21.7 62.3 11.6 4.3 3.01 0.72 10
4.7 Discussion of findings
4.7.1 Factors responsible for increase in the cost of building materials
One of the objectives of this study is to examine factors responsible for increase in cost of
building material that hinders sustainable housing delivery, as earlier stated. In this section,
the study considers factors related to the economy, building production processes,
stakeholders and external factors.
82
4.7.1.1 Economic related factors
The findings reveal inflation, with a mean value of 3.55, as the most significant economic
factor responsible for increase in the cost of building materials (see Table 4.4). The
construction industry is exposed to inflation in cost of building materials since it involves a
truly excessive use of building materials for erecting building (Oghenekevwe et al., 2014).
One of the principal goals in any economy is price stability (Oyediran, 2003). However, with
the rate at which inflation is presently ravaging global economies, particularly in developing
countries, this seems to be an uphill task (Monye-Emina, 2007). Kaming et al. (1997)
indicated that inflationary increases in building material cost are the main cause of
construction cost overrun. The finding also indicated that exchange rate of Rand and interest
rates are additional factors responsible for increase in the cost of building materials. In the
assessment, Owoeye (2003) posited one factor influencing exchange rate as the inflation
rate. The findings of Agene (1991) further supported that changes in imports and exports of
any country will immediately affect the rate of exchange for its currency. Interest rates and
inflation affect the value of investment, thereby hindering economic growth (Donald, 2005).
To concur, Windapo and Cattell (2013) observed that high interest rates pose as a huge
challenge to the construction industry because they are the prime default by construction
industry clients.
4.7.1.2 Building production process related factors responsible for increase in cost of
building materials
This study explored the perception of the respondents concerning building production
process related factors responsible for increase in the cost of building materials. The study
also evaluated the site related factors, human related factors and the design related factors.
4.7.1.2.1 Site related factors
Material waste has been acknowledged as the most important problem in the construction
industry with significant consequences both for the productivity of the industry and for the
environmental impact of construction projects (Gulghane et al., 2015:62). Findings from this
study revealed that waste of building materials by labourers is indeed a significant factor
responsible for increase in the cost of building materials (Table 4.5). The factor has a mean
value of 3.31. Wastages of building materials by labourers on site can be attributed to lack of
83
supervision or lack of skilled labour. This is in affirmation to the study undertaken by
Nagapan et al. (2012) showing that a significant percentage of labour has little or no
experience in construction. Therefore, inexperienced foremen add to more substandard
works and reworks as well as inexperienced field supervisor (Nagapan et al., 2012). The
findings also indicated that poor site planning preventing easy movement of materials is
another major factor responsible for increase in the cost of building materials. Inadequate
planning and poor control may lead to rework of a building. Equally, the lack of planning of
construction activities contributes to material waste (Polat & Ballard, 2004). Other factors
indicated by the findings include inadequate infrastructural facilities and unsuitable location
for building materials storage.
4.7.1.2.2 Human related factors
The findings revealed cost of transportation and distribution of labour (mv=3.28), cost of
power supply (mv=3.24), cost of labour (mv=3.17) and cost of plant (mv=3.13) were the
primary human related factors responsible for increase in the cost of building materials.
Insufficiency of skills on the part of construction labourers frequently results in construction
rework, reduced speed of work and overall disturbance of the general construction
performance (Ameh & Osegbo 2011; Soham & Rajiv 2013; Durdyev et al., 2012). High
transportation costs have a knock on effect on the labours, as high transport cost has been
acknowledged as a factor responsible for increase building materials costs in some
developing countries in Africa (Windapo & Cattell, 2012:191). The findings also revealed that
a communication problem between labourers and supervisors was another factor
responsible for increase in the cost of building materials. Takim (2009) proposed that
communication proficiency should be encouraged to attain greater efficiency and uniformity
in decision making.
4.7.1.2.3 Design related factors
This study explored the perception of construction stakeholders concerning design related
factors responsible for increase in the cost of building materials. Several studies
acknowledge the adverse impacts of client/design professionals on construction project
performance. The findings show that design changes (with a mean value of 3.36) and
additional work due to change in design (m=3.29) are design related factors responsible for
increase in the cost of building materials (Table 4.5). Design changes may well contribute to
additional works (Han et al., 2013). Change in construction design is inevitable and can arise
for a number of reasons. However, these design changes do require extra time, extra cost
84
and extra materials. This concurs with Al-Dubaisi (2000) who determined that a change in
design will have an impact on the material cost, schedule and cost of labour. Also, the
findings identified the wrong method of estimation by quantity surveyor as a factor
responsible for increase in the cost of building materials. This leads to rework which will
naturally increase material cost. Most rework circumstances arise from changes, damages,
defects, mistakes and errors (Rahman et al,. 2015). A study undertaken by Love et al.
(2002) highlighted rework as a major factor adding to cost escalations and time delays in
construction projects. Other factors indicated by the findings include construction design
complexity and additional work due to errors.
4.7.1.3 Stakeholder related factors responsible for increase in the cost of building
materials
Constructions stakeholders are representatives of a crew of individuals who, directly or
indirectly, have collective beneficial interests in a project (before and at the end of a project);
occasionally they can incur huge losses during construction (Smith et al., 2001; Lim & Yang,
2008). Clients are individuals or establishments principally responsible for introducing
construction ideas, and outlining project scopes and specifications (Doloi, 2013; Azmy,
2012). Client contribution to design changes is ranked as the primary stakeholder related
factor responsible for increase in the cost of building materials (Table 4.6), as this factor has
a mean value of 3.28. Change might occur as a result of newly-emerging ideas perceived by
the client for the project to fulfil desired functional and socio requirements. Irrespective of the
client’s reason, change ordered by clients will arguably have an effect on the cost of
construction activities, especially major changes. The investigation of Yana et al. (2015)
revealed that a client is the chief significant factor in the incidence of design changes.
Further, the findings of this study show that incorrect construction method and improper
planning are others factors under stakeholder related factors. Proper scheduling is essential
in project resources utilization, as lack of this will increase the project cost (Eshofonie, 2008)
4.7.1.4 External related factors responsible for increase in cost of building materials
The external factors responsible for increase in the cost of building materials are the factors
that are not attributed to individual participants in the construction sector. Proper processes
are an absolute necessity for reducing the impact of external factors on cost of building
materials. The most notable external factor responsible for increase in the cost of building
materials is change in government policies and regulation (mv=3.02). Government
legislations (mv=30.1) and lack of substitute for product (mv=3.00) are the next two highest
85
rated factors responsible for increase in the cost of building materials (Table 4.7). Dlakwa
and Culpin (1990: 238) and Adekoya (2003:29) noted government fiscal policies as one of
the factors affecting the cost of building materials. Force majeure factors (outbreak of war,
hostilities, uprisings, for example) received a low rank because they rarely impinge upon the
South Africa construction industry.
4.7.1.5 Effects of increase in the cost of building materials on housing delivery
The analysis of quantitative data collected for this research and reviewed literature depict
that increase in the cost of building materials has an effect on affordable housing delivery in
the Western Cape of South African. The increase in the cost of building materials poses a
significant threat to the construction industry. The findings from the study (Table 4.8) show
fluctuation in cost of construction (with mean value of 3.26) as the most notable effect of
increase in the cost of building materials on housing delivery. The client and project
contractors have been facing serious trials in trying to maintain steady cost projection on
construction projects (Akanni et al., 2014). Clearly, cost control during the construction
process is important to ensure the success of a project (Nega, 2008).
The findings also indicated that high maintenance cost due to poor workmanship, increase in
the cost of repair due to inferior materials used, client expectations pertaining to quality
project delivery, and building collapses due to the use of lesser quality materials are all
effects of an increase in cost of building materials on housing delivery. Iwaro and Mwasha,
(2012) highlighted that workmanship plays an important role in project quality, especially as
one of the characteristics of a developed construction industry is in the output of quality
buildings and structures (Lam et al., 2007). However, Oyedele and Tham (2006:2091) posit
that lack of significant consideration for design constructability may cause building collapse
during the construction process. Therefore, stakeholder satisfaction and timely project
completion are yardsticks for measuring project success in relation to time, quality, scope
and cost (Mallak, Patzak & Kurstedt, 1991; Takim, 2009; Pinder, Schmidt & Saker, 2013).
4.7.1.6 Influence of stakeholders in materials selection
The material selection technique is a part of the building process, taking into account that
stakeholders are not typically regarded as a part of the process. Takim (2009) and Yudelson
(2010) stated that for effective management of construction and to ensure efficiency during
construction, a combined project team should accommodate a wide range of stakeholders –
client, general contractors, architects, project managers, consultants, engineers and
86
government agents/commissioning authorities – depending on the complexity of the project.
The findings reveal that the client (mv=3.43) has the highest degree of involvement in
material selection, followed by architect and designer, technical consultant, project manager,
quantity surveyor, in this order respectively (Table 4.9). The client involvement is
understandable as the client holds the primary responsibility for estimating the activities
during the course of the production process, as well as setting priorities (Akadiri, 2011). The
importance of the client can further be reflected by the various ways of influence and
exerting pressure on project partakers in order to improve building life cycle performance
(Gann & Salter, 2000). The relationship between client and architect (designer) is paramount
in creating and carrying out design decisions during the course of the construction. This
shows the essential role of clients in influencing designer’s environmental strategies.
4.7.1.7 Guidelines to materials selection in construction towards enhancing
sustainable building delivery
Selection of sustainable building materials in building projects is an essential decision in
sustainability practices. Alibaba (2004:307) and Nasar et al. (2003:543) highlighted that one
of many factors impacting the sustainability of building delivery is precisely this: the selection
of building materials. One of the simplest ways to incorporate sustainable principles in
building projects is by careful selection of sustainable building materials (Akadiri et al., 2013:
113). A number of researchers have delineated guidelines for which considerations are
important in selection of sustainable building materials. Based on this information, the study
investigated guidelines to materials selection in construction towards enhancing sustainable
building delivery, with findings revealing these factors: building design, environmental
impacts of materials, material life cycle cost, material functional demands, material market
trend demands, technological impact of materials, material structural demands and material
efficiency (use of renewable and recyclable materials) (Table 4.10). All these guidelines
identified have a mean score of 3, signifying that the respondents agreed that the identified
guidelines are significant towards enhancing sustainable building delivery.
4.7.1.8 Sustainable criteria for building materials selection
One of the main objectives of this research was to ascertain the criteria to be considered in
the selection of building materials for sustainable housing delivery. The prospect of
sustainable construction is enhanced, both to meet society's environmental goals and
account for social wellbeing, as well as address the economic impact of building projects.
Thus, the criteria chosen should cover all four categories – economic, environmental, social
87
and technical – to ensure that attention is being given to progress towards sustainability
objectives. As noted in an earlier chapter, to develop sustainable housing, housing initiatives
must be socially acceptable, economically viable, environmentally friendly and technically
feasible (Choguill, 1999). A list of assessment criteria (Table 4.11) was developed, identified
under three categories: socio-economic, environmental and technical.
4.7.1.8.1 Socio- economic criteria
Table 4.11 reveals the perception of respondents on socio-economic criteria to be
considered in the selection of building materials. Maintenance cost (with a mean value of
3.36) was ranked as the first priority in selection of sustainable building materials. High
maintenance costs have intense negative effects on stakeholders and the construction
industry as whole (Mbachu & Nkado, 2004). Building maintenance cost can be reduced with
a thorough knowledge of building maintenance cost theories (Faremi et al. 2015). The
findings also reveal health and safety and initial cost as notable priorities to be considered in
the selection of building materials. Initial costs have long been a major concern for
stakeholders in the building industry (Akadiri, 2011).
4.7.1.8.2 Environment criteria
The finding shows energy consumption, environmental pollution, air quality and low or non-
toxicity as the major criteria to be considered in the selection of building materials (Table
4.11). Effective uses of energy help reduce energy intake in buildings and facilities (Sharma
& Mehta 2014:82). Material toxicity issues are of paramount importance to all project
participants. Akadiri (2011) posited that using low volatile organic compound materials for
construction can considerably decrease the emission volatile organic compounds. This has
been acknowledged by the industry as a vital factor to any successful project, a significant
step to sustainable construction.
4.7.1.8.3 Technical criteria
The findings reveal maintainability (with a mean value of 3.43) as the most significant factor
to be considered in the selection of sustainable materials. Maintainability has long been a
major concern among architects and designers in the construction industry. Thus,
maintenance free buildings are increasingly sought by clients, so as to reduce the running
88
costs associated with maintaining buildings (Akadiri, 2011). The findings also reveal life
expectancy of material in term of strength and durability, fire resistance, and resistance to
decay (Table 4.11) as other notable factors to be considered in the selection of sustainable
building materials.
4.7.1.9 Project factors
Table 4.12 revealed client preference (with a mean value of 3.55) as factor that determines
the nature and type of materials to be selected. The client has a significant impact on the
choices made by architects, as the client wields the power to hire (Folorunso et al., 2017).
Thus, this suggests that clients have a substantial role to play in the choice of building
materials. Complexity of project, budgeted project, cost scope of project and stakeholder
expectations are other factors that determine the type of materials to be selected.
Table 4.13: Summary of findings of quantitative data
S/N CONCEPTS ISSUED ADDRESSED FINDINGS
1.0 To identify factors responsible for increase in the cost of building materials that hinders sustainable housing delivery
1.1 Economic related factors 1. Inflation 2. Exchange rate of rand 3. Interest rate 4. Cost of building materials 5. Market condition
1.2 Site related factors 1. Wastages of building materials by workers
2. Poor site planning prevents easy movement of materials
3. Inadequate infrastructural facilities
4. Unsuitable location for building materials storage
1.3 Human related factors 1. Cost of transportation and distribution of labour
2. Cost of power supply 3. Cost of labour 4. Cost of plant 5. Communication problem between
labourer and supervisors.
1.4 Design related factors 1. Design changes 2. Additional work due to change in
design 3. Wrong method of estimation by
quantity surveyor 4. Construction design complexity 5. Additional work due to errors
1.5 Stakeholder related factors 1. Client contribution to design change
2. Incorrect construction method 3. Improper planning 4. Client demand on high quality
project delivery 5. Supplier default
1.6 External factors 1. Change in government policies
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and regulation 2. Government legislations 3. Lack of substitute for product 4. Level of advanced technology 5. Increase in the cost of hiring
construction machineries
2.0 To evaluate the effects of increase in the cost of building materials on the delivery of affordable housing
2.1 Effects of increase in the cost of building materials on housing delivery
1. Fluctuation in cost of construction 2. High maintenance cost due to
poor workmanship 3. Increase in the cost of repair due
to inferior materials used 4. Poor workmanship 5. Affect client expectation on
quality project delivery
3.0 To ascertain the criteria to be considered in the selection of building materials for sustainable affordable housing delivery
3.1 Influence of stakeholders in materials selection
1. Client 2. Architect and designer 3. technical consultant 4. Project manager 5. Quantity surveyor
3.2 Guidelines to materials selection in construction towards enhancing sustainable building delivery
1. Building design 2. Environmental impacts of
materials 3. Material life cycle cost, 4. Material functional demands 5. Material market trend demands
3.3 Socio-economic criteria, 1. Maintenance cost 2. Health and safety 3. Initial cost 4. Disposal cost 5. Aesthetics
3.4 Environmental criteria 1. Energy consumption 2. Environmental pollution 3. Air quality 4. Low or non-toxicity 5. Sound disposal options
3.5 Technical criteria 1. Maintainability 2. life expectancy of material
(strength, durability) 3. Fire resistance 4. Resistance to decay 5. Energy saving and thermal
insulation
3.6 Project factors 1. Client preference 2. Complexity of project 3. Budgeted project cost 4. Scope of project 5. Stakeholder expectation
4.8 Validity assurance of the quantitative research results
This section was conducted to assess the validity of the quantitative data obtained by the
questionnaires. Basically, the validity assurance of research results shows how applicable
the obtained results are in the field of study. Thomas and Magilvy (2011) established that the
validity of research is the level to which the data acquired evaluates accurately that which it
was intended to measure. To ensure that the research results are valid and reliable, the
following steps were considered:
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a. Research population: The population sampled for this study included construction
stakeholders in the construction industry in the Western Cape of South Africa. This
population was identified for achieving reliable results (Section 4.3).
b. Expected participants: Experienced construction stakeholders within the industry are the
targets (Section 4.3 & Table 4.1).
c. Sampling technique: The cluster sampling method was adopted for data collection in this
study as the use of cluster sampling redistributes the target population (with high
concentration of construction companies and experienced professionals) into smaller groups
(clusters) from which samples are randomly selected for data collection and result
generalisation (Section 3.7.4).
d. Time: The data were collected with a considerable time limit.
e. Data collection instrument: The most accurate data collection tool was adopted for each
phase of collection (Section 3.7.1 and Section 4.1).
f. Exploratory/pilot study: The exploratory study was conducted to determine the reliability
and accuracy of the data collection method to be adopted for the main study (Section 3.7.2
and 4.2).
g. Cronbach’s alpha co-efficiency analysis: The Cronbach’s alpha co-efficient analysis was
conducted to test the reliability of the quantitative research question in this study (Section
4.3).
h. Interview sessions: The interview sessions with the respondents were recorded using a
mobicel mini ipad smart recorder and analysed using the statistical package software
(SPSS, version 24).
4.9 Validation of findings
The qualitative collection phase adopted the construct validity technique. Construct validity is
a technique adopted to ensure that the findings obtained in this research measure what the
study claimed to measure. The findings from the quantitative data analysis were framed into
interview questions to confirm if the quantitative results answered what was intended in
regard to the research aim and objectives. Three (3) construction organisations were
selected for the interview. The researcher scheduled appointments for each interview with
the respondents to ensure efficient research time management. Four (3) constructional
professional were interviewed on construction sites A, B, and C. The interview session
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conducted with each interviewee started with an introduction of research title and
explanation of the underlying purpose of the study. The interview was then recorded with a
devise and subsequently transcribed. A copy of the interview questions is found in Appendix
B
Table 4.14: Demographic of qualitative respondents
Respondent Qualification Position Years of experience in
construction industry
Years of experience in the
present position
A Bachelor’s
degree
Site supervisor 12 years 8 years
B Honour’s
degree
Project
manager
22 years 9 years
C Bachelor’s
degree
Site supervisor 14 years 5 years
Interview with respondent A
The first interview was conducted on July 17, 2017, at 16h00min. An experienced project
manager who is presently working in the public sector of the construction industry was
interviewed. The site supervisor interviewed holds a Bachelor’s degree with twelve (12)
years’ work experience in the construction industry and eight (8) years of experience in the
present position. The interview lasted for forty one minutes as the interviewee responded to
each interview question with enthusiasm. The interview discussion was recorded using a
‘Smart recorder app’ installed on mobicel iPad mini. A copy of the interview outline is found
in Appendix B. The respondent stated the following:
Inflation and interest rate under the economic related factors are the most significant
factors responsible for increase in the cost of building materials.
The process involved in building production plays a significant role in the cost of building
materials, especially considering the poor site planning, wastage of materials by workers
and wrong method estimation prepared by some quantity surveyors.
External factors such as climate changes in weather condition and natural occurrences
could also be responsible for an increase in the cost of building materials.
From experience, a common effect of increase in the cost of building materials is
fluctuation; that is, in the sense that when material prices are not stable due to inflation,
the contract or construction sum fluctuates, thereby affecting timely housing delivery to
the populace.
Conflict between client and contractor is also an effect of increase in the cost of building
materials. Increase in the contract sum easily leads to disputes between involved
stakeholders, leaving some disgruntled and dissatisfied.
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When selecting building materials for sustainable building delivery enhancement,
building design and specification, environmental impact of materials, material efficiency
and market trends are key guidelines which to be cognisant.
To my own knowledge, different stakeholders have different criteria for selecting building
materials depending on the client choice and budgeted project cost and complexity of the
project. However, in my opinion, the following could be considered as selection criteria:
durability of materials, health and safety, aesthetics, environmental pollution, low or non-
toxity, maintainability and material availability.
In my own opinion, different measures from different perspectives can be taken to
enhance sustainable housing delivery. Government should ensure stable and viable
regulations of the cost of building materials. Maintenance practices should be adhered to
by suppliers, transporters and end users of building materials. There should be
accessible road network from the loading site to the offloading site so transportation cost
would be minimal. Materials should be produced with the most affordable and
sustainable products, thereby end users can purchase at optimum cost while at the
same time enjoying best value for money on the materials. Sustainable practices should
be implemented in all facets of building production in the construction industry, including
manufacturers, suppliers, workers and end users. If possible, construction activities
should be insured, thereby minimising risk of uncertainty.
Interview with respondent B
The second interview was conducted on July 20, 2017, at 13h05mins. The interview was
conducted with an experienced project manager who is presently working in the public
sector of the construction industry. The project manager interviewed holds an Honour’s
degree with twenty-two (22) years’ work experience in the construction industry and nine (9)
years of experience in the present position. The interview lasted for about forty five minutes
as the interviewee responded to each interview question after being read out by the
interviewer from the interview guideline. The interview discussion was recorded using a
‘Smart recorder app’ installed on mobicel iPad mini. A copy of the interview outline is found
in Appendix B.
The respondent opined that inflation and exchange rate of Rand to other foreign
currencies are factors responsible for increase in the cost of building materials. The
respondent further stated that some building materials are being imported from other
countries in a quest to meet client demand and expectation on specifically requested
building materials which are not available here in South Africa.
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Building production phase is a vital phase which requires proper planning and
effective communication. Lack of planning and poor communication between
supervisor and labourers can lead to increase in cost of building materials due to
waste of construction materials by labourers.
The respondent further stated other factors responsible for increase in the cost of
building materials are additional works due to error in the drawing and client
contribution to change in the design. All these factors will automatically result in
change in the design.
Constant changes in government regulations and lack of substitutes for some
building materials are the external factor responsible for increase in the cost of
building materials.
In my own opinion and experience in the construction industry, effects of increase in
the cost of building materials are construction cost escalation, final cost production
higher than budgeted and poor workmanship which in turn leads to high maintenance
and repair cost.
The respondent further stated that an increase in the cost building materials has an
adverse effect on client expectation of quality project delivery. In order to avoid
conflict between clients and contractors, some contractors use substandard quality
materials to meet the client budget requirement, and in this manner impact the client
expectations of quality.
In my own opinion, some guidelines that we should be aware of when selecting
building materials towards sustainable housing delivery are material life cycle cost,
building design, socio-economic impact of materials and environmental impact of
materials.
The respondent stated that selection of material depends on the client preference,
scope of project and project cost budgeted. The respondent identified these criteria:
maintenance cost, fire resistance, strength of the materials, health and safety,
maintainability energy saving and thermal insulation.
The project manager advised that the use of sustainable locally made building
materials, rather than sophisticated building materials and techniques that are costly
and energy consuming, should be encouraged by government as this will enhance
affordable housing delivery. This will make the material cost effective and produce
sustainable housing provisions. The project manager counselled that in order to
enhance sustainable housing delivery, stakeholders should ensure proper
monitoring, planning and controlling of the project at all stages during production to
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avoid increases in construction costs that are always categorized as project delivery
that is above budgeted cost.
Interview with respondent C
The third interview was conducted on July 31, 2017, at 13h25mins. The interview was
conducted with a construction site supervisor. The site supervisor interviewed holds a
Bachelor’s degree with fourteen (14) years’ work experience in the construction industry and
eight (8) years of experience in the present in the position. The interview lasted for about 40
minutes as the interviewee responded to each interview question after being read out by the
interviewer from the interview guideline. The interview discussion was recorded using a
‘Smart recorder app’ installed on a mobicel iPad mini. A copy of the interview outline is found
in Appendix B.
The respondent stated that economic instability of the country is a contributory factor
of the cost increase of building materials. The respondent further stated that price
stability depended on the economic situation. However, the price of building materials
has been vacillating, which can be attributed to inflationary trends. Interest rate
charged by banks is also a factor responsible for increase in cost of building
materials under economic factors.
The respondent opined that building production processes involved the use of
manpower. Cost of transportation of labours, cost of labour and wastages of building
materials on site by labourers are factors responsible for increase in the cost of
building materials.
The site supervisor further claimed lack of communication between the labourers
and stakeholders involved on site as another factor responsible for increase in cost of
building materials. The respondent explained that team work practices are a major
aspect of handling the building production process; this helps to achieve project
objectives and the delivery of a project at budgeted cost, time and quality expected.
The site supervisor stated that the meeting client expectation during the production
process begins from the design stage, after the client briefing. Failure by the design
team to incorporate client requirements into design detailing will be conveyed to the
preparation of the bill of quantity, which then impacts budgeted costs.
As for external factors responsible for increase in the cost of building materials, the
respondent said that force majeure rarely happens in South Africa as in other
countries, though when something occurs, it does affect cost building materials due
to deterioration and destruction of some materials. The respondent further said that
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government regulations and policies play a significant role in the economic instability
of cost of building materials.
The respondent stated that increase in the cost of building materials has a massive
effect on the timely delivery of housing. Building materials consume up to 60% of all
construction costs. He further stated that increase in the cost of building materials will
push the cost of construction higher than estimated project cost.
Another effect, with my experience in the industry, is conflict between client and
contractor due to the increase in project budgeted cost and delay in the progress of
project works. The respondent further noted that late delivery of materials to site is
the major cause of construction cost and time overrun.
The respondent identified some important guidelines to be followed when selecting
building materials: it is important to cognisant of economic, environmental and
technological impacts on materials.
In my own knowledge, criteria for selecting building materials differ depending on the
type of project involved. However, in my opinion, the following could be considered
as selection criteria: durability of materials, health and safety, aesthetics,
environmental pollution, ease of construction, maintainability and energy
consumption.
The respondent explained that in order to enhance sustainable housing delivery,
some steps must be established. The availability of materials on site is very
important, as this determines the speed at which the work is completed and will
reduce materials wastage and cost towards economic sustainability. Sustainability
should be encouraged and practiced in all phases of building production.
Government should enact some regulations that will govern the prices of building
materials so as to prevent any manipulation from materials supplier due to high
demand of these materials. He further stated that government should pay particular
attention to cost of transport, crude cost and energy cost for the efficient and effective
distribution of the products from suppliers to end-users.
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Table 4.15: Summary of qualitative interviews
Factors Respondent A Respondent B Respondent C
Factors responsible for
increase in the cost of
building materials
Inflation and interest. Inflation and exchange
rate of rand to others
foreign currencies.
Inflation and interest
Building production
processes responsible
for increase in the cost of
building materials
Poor site planning, wastage
of materials by workers and
wrong method estimation
prepared by quantity
surveyor.
Waste of construction
materials by labourers,
design changes and
communication problem
between labourers and
supervisors.
Cost of transportation of
labours, cost of labour,
wastages of building
materials on site by
labourers and lack of
communication between
labourers and
supervisors
External factors
responsible for increase
in the cost of building
materials
Climate changes in weather
condition and natural
occurrences
Change in government
regulations and lack of
substitute for some
building materials
Change in government
policies and regulation
Effects of building
materials cost on
housing delivery
Fluctuation in the cost of
construction and conflict
between client and
contractor
Construction cost
escalation, final cost of
production higher than
budgeted and poor
workmanship which will
in turn leads to high
maintenance and repair
cost
Conflict between client
and contractor due to the
increase in project
budgeted cost and delay
on the progress of project
works
Guidelines that need to
be followed or adopted
when selecting building
materials
Building design and
specification, environmental
impacts of materials,
materials efficiency and
market trends
Life cycle cost, building
design, socio economic
impact of materials and
environmental impact of
the materials
Economic impact of
materials, environmental
and technological impact
of materials
Criteria for the selection
of building materials
Durability of materials,
health and safety,
aesthetics, environmental
pollution, low or non-toxity,
maintainability, and material
availability
Maintenance cost, fire
resistance, strength of
the materials, health
and safety,
maintainability energy
saving and thermal
insulation.
Durability of materials,
health and safety,
aesthetics, environmental
pollution, ease of
construction,
maintainability and
energy consumption
Measures that can be taken to enhance sustainable housing delivery
Government should ensure stable and viable regulation of cost of building materials.
Adoption in the use of sustainable locally made building materials
Availability of materials on site this determines the speed at which the work is completed, reduce materials wastage and cost towards economic sustainability
4.10 Achieving the objectives of the research study
The first objective of this study concerned examining factors responsible for increase in the
cost of building materials. In achieving the objective, the data collected were analysed and
the major findings were centred on economic related factors, building production process
related factors, stakeholder related factors and external related factors. Inflation, exchange
97
rate of rand, interest rate, cost of building materials, market conditions, fluctuation in the cost
of raw materials, local taxes and supply and demand of building materials are significant
economic related factors responsible for increase in the cost of building materials, as
presented in Table 4.4.
The findings also show building production process related factors that are responsible for
increase in the cost of building materials. This was comprised of three sub-questions
regarding building production process related factors responsible for increase in the cost of
building materials. The objective was achieved through the investigation of site related
factors, human related factor and design related factors, presented in Table 4.5. Achieving
the objective, the findings obtained after data analysis under site related factors are as
follows: wastages of building materials by workers, poor site planning preventing easy
movement of materials, inadequate infrastructural facilities and unsuitable location for
building materials storage. Major findings under human related factors are as follows: cost of
transportation and distribution of labour, cost of power supply, cost of labour, cost of plant
and communication problems between labourer and supervisors. Under design related
factors, the findings are as follows: design changes, additional work due to change in design,
wrong method of estimation by quantity surveyor, construction design complexity, additional
work due to errors, design team experience and inadequate coordination among design
team.
In terms of the impact of stakeholder related factors on increase in the cost of building
materials, findings in Table 4.6 shows that client contribution to design change, incorrect
construction method, improper planning, client demand on high quality project delivery,
supplier default and delay in the supply of materials on site are stakeholder related factors
responsible for increase in the cost of building materials. Finally, this study investigated the
external related factors responsible for increase in the cost of building materials. Achieving
this objective, the finding obtained after data analysis, in Table 4.7, are as follows: change in
government policies and regulation, government legislations and lack of substitute for
product are the external related factors responsible for increase in the cost of building
materials.
The second objective of this study was to evaluate the effects of increase in the cost of
building materials on the delivery of affordable housing. The objective was achieved and
findings obtained are as follows in Table 4.8: fluctuation in cost of construction, high
maintenance cost due to poor workmanship, increase in the cost of repair due to inferior
materials used, poor workmanship, impact of client expectation on quality project delivery,
building collapse due to the use of less quality materials, conflict between client and
98
contractor due to upward review of contract sum, delay on the progress of project works,
poor quality of construction product, increase in final cost of building products, final cost of
production higher than budgeted, high rate of contractor fraudulent practices, low income
earners priced out for home ownership due to high cost of building, impact on the aesthetic
value of building product, shortage in the delivery of housing to the populace, the gross
domestic product (GDP) contribution to the economy, investment return on construction
project delayed, and threatening health and safety of workers on site. These are the
significant findings of concerning the effects of increase in the cost of building materials on
the delivery of affordable housing.
The third objective of this study was to ascertain the criteria to be considered in the selection
of building materials for sustainable fordable housing delivery. In achieving this objective, the
data collected were analysed and the major findings were centred on the influence of
stakeholders in material selection, guidelines for materials selection in construction towards
enhancing sustainable building delivery, sustainable criteria to be considered for building
materials selection and project factors in the selection of building materials for sustainable
housing.
The findings in Table 4.9 show that client, architect, designer and technical consultant are
the stakeholders who have a significant influence in the selection of sustainable building
materials for affordable housing. Other major findings, presented in Table 4.10, also show
that building design, environmental impact of material, material life cycle cost, material
functional demands, and material market trend demands, technological impact of materials,
material structural demands, and material efficiency are guidelines to material selection in
construction towards enhancing sustainable building delivery.
However, the findings also show the criteria to be considered in the selection of sustainable
building materials under the sustainability categorised. This is comprised of three sub-
questions under the sustainability criteria. The objective was achieved through the
investigation of socio-economic criteria, environmental criteria and technical criteria.
Achieving the objective, the findings obtained after data analysis, as presented in Table
4.11, are as follows: maintenance cost, health and safety, initial cost, disposal cost,
aesthetics and labour availability are the socio-economic criteria for selection of sustainable
building materials.
Environmental criteria for selection of sustainable building materials were also investigated.
Findings show that energy consumption, environmental pollution, air quality, low or non-
toxicity, sound disposal options, embodied energy in the material, environmental statutory
99
compliance, green gas emission and amount of likely wastage in the use of materials are
criteria for the selection of sustainable building materials for affordable housing.
This study investigated the technical criteria for selection of sustainable building materials.
The findings obtained after data analysis are as follows: maintainability, life expectancy of
material (strength, durability), fire resistance, resistance to decay, energy saving and thermal
insulation, moisture resistance, ease of construction, material availability and sound
insulation are criteria for the selection of sustainable building materials for affordable
housing.
Other major findings also show project factors that determine selection of sustainable
building materials. The findings obtained after data analysis, as presented in Table 4.12, are
as follows: client preference, complexity of project, budgeted project cost, scope of project,
stakeholder expectation, project schedule, project size, site condition, nature of the project
and type of project are factors that determine selection of sustainable building materials for
affordable housing.
Objective five of this study is to establish solutions to factors causing increase in the cost of
building materials towards sustainable affordable housing delivery. The objective was
achieved through the identified factors that are responsible for increase in the cost of
building materials; through the identified economic related factors, building production
process related factors, stakeholder related factors and external related factors, effects of
increase in the cost of building materials on the delivery of affordable housing, criteria to be
considered in the selection of sustainable building materials for affordable housing; through
the assessment of the influence of stakeholders in materials selection, guidelines to
materials selection in construction towards enhancing sustainable building delivery,
sustainable criteria to be considered for building materials selection and project factors in the
selection of sustainable building materials for affordable housing. The findings derived from
the analysed data are illustrated in Tables 4.4, 4.5, 4.6, 4.7, 4.8, 4.9, 4.10, 4.11 and 4.12.
The findings were used to establish solutions to factors causing increase in the cost of
building materials towards sustainable housing delivery. A summary of the key findings is
presented in Figure 4.6.
4.11 Operational framework
Figure 4.6 presents the operational framework to enhance sustainable housing delivery.
Adequate application of the recommendations presented in this study will significantly
100
reduce factors causing increase in cost of building materials on housing delivery, and
construction time and cost overruns, and ultimately, increase stakeholder satisfaction.
Figure 4.6: Operational frameworks for enhancement of sustainable housing delivery
4.12 Chapter summary
This chapter presents an analysis of data, along with a presentation and discussion of
findings. The data collected were analysed using the Statistical Package for Social Sciences
(SPSS) software, version 24. Descriptive statistics were used in the study. The survey
questions were scaled and tested for reliability using Cronbach's alpha coefficient. The
average Cronbach’s alpha coefficient for the questions was 0.8, indicating that the questions
are reliable.
The findings revealed that inflation, exchange rate of rand and interest rate are the
significant economic related factors responsible for increase in the cost of building materials.
Wastages of building materials by labourers cost of transportation and distribution of labour
and design changes are the major site, human and design related factors responsible for
increase in the cost of building materials. Client contribution to change is a key stakeholder
To examine factors
responsible for
increase in the cost
of building materials
that hinders
sustainable housing
delivery
To evaluate the
effect of the
increase in the cost
of building
materials on the
delivery of
affordable housing
To ascertain the
criteria to be
considered in the
selection of
sustainable building
material for
affordable housing
To establish solutions to
the factors causing an
increase in the cost of
building materials towards
sustainable hosing
delivery
Economic
related
factors
Building
production
related
factors
Stakeholders
related
factors
External
factors
Fluctuation in the
cost of
construction
High
maintenance
cost due to poor
workmanship
Increase in cost
of repair due to
inferior materials
used
Table 4.13
Stakeholders’
influence
Guidelines
Socio-
Economic
criteria
Environmental
criteria
Technological
criteria
Project factors
Objective1
Objective2
Objective3
Objective4
Established solutions to
the factors causing
increase in the cost of
building materials to
enhance sustainable
housing delivery.
Summary of findings of analysed quantitative data
Table 4.13
Summary of findings of analysed qualitative data
Table 4.15
101
related factor responsible for increase in the cost of building materials. Respondents
indicated that change in government policies and regulation, government legislations and
lack of substitute for products are the important external related factors. The interview
respondents agreed that the effects of increase in the cost of building materials on housing
delivery is due to fluctuation in the cost of construction. The findings also revealed that high
maintenance cost due to poor workmanship, increase in the cost of repair due to inferior
materials and poor workmanship are major effects of increase in the cost of building
materials.
Respondents indicated that the client has a significant influence on material selection. The
findings revealed that building design, environmental impact of materials and material life
cycle cost are guidelines of which to be cognisant when selecting building materials. Major
sustainability categories (socio-economic, environmental and technical criteria) to be
considered for selection of building materials are maintenance cost, energy consumption
and maintainability. The findings also revealed client preference, complexity of project and
budgeted project cost are factors determining sustainability criteria for selection of building
material for enhancement of sustainable housing delivery in Western Cape in particular, and
South Africa in general.
102
CHAPTER FIVE
SUMMARY, CONCLUSIONS AND RECOMMENDATIONS
5.1 Introduction
The data derived from the quantitative and qualitative survey on this – ‘effect of building
materials cost on housing delivery towards sustainability in Western Cape, South Africa’ –
were analysed and discussed. Conclusions and recommendations were made based on the
obtained results. This study aimed to investigate the effects of building material cost on the
delivery of affordable housing towards sustainability in the Western Cape, South Africa. The
objectives of this study were as follows:
1. to examine factors responsible for increase in the cost of building materials that hinder
sustainable housing delivery;
2. to evaluate the effects of increase in the cost of building materials on the delivery of
affordable housing;
3. to ascertain the criteria to be considered in the selection of building materials for
sustainable affordable housing; and
4. to establish solutions for factors causing increase in the cost of building materials towards
sustainable affordable housing delivery.
5.2 Summary
Based on the literature reviewed and findings obtained through mixed method of data
collection, Table 5.1 presents the summary of research outcomes.
Table 5.1: Summary of research study
S/N Concept Reference Page
I. Conceptual framework Figure 1.1 4
. Research method Figure 3.3 64
Summary findings of quantitative study Figure 4.13 88
Summary findings of qualitative study Figure 4.15 96
Operational framework for the study Figure 4.6 100
103
5.3 Conclusion
The adoption of these findings by construction stakeholders in the South African construction
industry would enhance the delivery of affordable housing whose process of construction
and life cycle of operation would promote healthy well-being of the occupants and
environmental stability, at reduced cost, required time and expected quality. Considering the
objectives of this study, these factors were discussed and achieved.
5.3.1 Factors responsible for increase in the cost of building materials that hinder
sustainable housing delivery
One of the objectives designed to achieve the purpose of this study is to identify factors
responsible for increase in the cost of building materials that hinder sustainable housing
delivery. This objective was achieved through the review of literature, exploratory study, and
administration of survey questionnaires to construction stakeholders and semi-structured
interviews with site supervisors. All the identified factors attracted more than a 50%
agreement rate from respondents. Therefore, it can safely be concluded that the majority of
the identified economic related, building production process related factors, stakeholder
related factors and external factors are significant factors responsible for increase in the cost
of building materials that hinder sustainable housing delivery in the Western Cape of South
Africa. Nonetheless, the most influential factors responsible for increase in cost of building
materials are essential to be noted, if improvement in cost effectiveness is to be achieved.
5.2.3 Effect of increase in the cost of building materials on the delivery of affordable
housing
The second objective of the study is to evaluate the effects of increase in the cost of building
materials on the delivery of affordable housing. This objective was achieved through a
review of relevant literature, an exploratory study, and administration of survey
questionnaires to construction stakeholder, along with semi-structured interviews with site
supervisors. Twenty three (23) factors were investigated. Findings reveal that fluctuation in
the cost of construction was identified as a major effect of the increase in the cost of building
materials on the delivery of affordable housing in Western Cape. The findings also revealed
high maintenance cost due to poor workmanship and increase in the cost of repair due to
inferior materials used as two others effects of increase in the cost of building materials on
housing delivery in Western Cape of South Africa.
104
5.3.3 Criteria to be considered in the selection of sustainable building materials for
affordable housing
Twenty nine (29) factors were identified as criteria to be considered in the selection of
sustainable building materials. These factors were further sub-divided into socio-economic
criteria, environmental criteria and technical criteria based on sustainability. This objective
was achieved through the review of relevant literature, the exploratory study, the
administration of survey questionnaires to construction stakeholder and semi-structured
interviews with site supervisors. The findings revealed maintenance cost as key socio-
economic criteria to be considered when selecting building materials. Findings also reveal
energy consumption as significant environmental criteria to be considered, and
maintainability as the key technical criteria to be considered in the selection of sustainable
building materials for affordable housing.
Effective consideration of building materials before selection in construction towards
enhancing sustainable housing delivery based on socio-economic, environmental and
technical criteria is a method to ensure that the sustainability supply chain requirements are
met at the initial phase of the project. This would allow construction stakeholders to verify
that the building production processes abide by the principles of sustainability from the early
stages of the building.
5.4 Limitations
This study was conducted in the Western Cape Province of South Africa. The collection of
data from construction stakeholders and contractors was a challenging task in the course of
the study as a result of the busy schedules of the respondents. The majority of the
respondents complained of their tight time schedules on site, attending contract meeting and
the pressure on them to meet certain project completion time. Some stakeholders on
construction sites complained of not having the time to answer any questions, and such
refusal to assist with this project tended to produce similar responses from their colleagues
working in the same office. Due to time constraints, a significant number of the
questionnaires were returned incomplete and therefore discarded by the researcher. As a
result, the findings of the study are only applicable to construction operations in the Western
Cape and cannot be generalised.
105
5.5 Conclusion and recommendations
The examined findings that are responsible for increase in the cost of building materials
during a production process, if effectively considered by stakeholders during the production
process, will improve delivery of a project at construction budgeted costs satisfactory to the
client. Increase in the cost of building materials has been narrowed down to economic
instability of this country. This has a significant impact on the manufacturer of building
materials, due to high cost of raw materials, forcing the manufacturers to increase cost of
building materials when produced. In order to provide lasting solutions, and bring about
steady building material prices and avoid circumstances of constant price increases, the
government should assemble building material monitoring committee that will bring
innovations in construction methods and materials research. Quarterly material research will
help curb the continuous increases in building material price. Government should support
and encourage the conducting of innovative research in the development of new local
building materials for production; this will reduce the reliance on expensive imported
materials.
Wastages of building materials by workers is a site related factor responsible for escalating
costs of building materials. This could be a result of the lack of communication between the
involved stakeholders and site workers and lack of material management. Construction
stakeholders are required to incorporate practical knowledge acquired in the industry and
intelligent management skills to effectively communicate about the project with site workers.
Additionally, effective material procurement management is required to avoid wastage of
building materials during building production process. Moreover, timely delivery of building
materials to site enables the effective usage of materials during construction and reduces
material wastages during production processes. Cost of transportation and distribution of
labour are the human related factors responsible for increase in the cost of building
materials. These are enormous challenges within the industry and require necessary
measures to curb the waste. Government should also take drastic measures to counter the
problem of transportation costs, cost of power supply, and increase in the fuel prices, to
improve ease of movement and distribution of raw materials to the factory as well as
distribution of the finished products from the factory to the end-user. Therefore, it is
recommended for proficiency and effective distribution of the finished products from factory
to suppliers and end-users, that the South African government develop long-lasting
highways and introduces high speed trains for transportation of goods and services which
include building materials.
106
Change in design is the identified top design related factor that is responsible for increase in
the cost of building materials. A change in design could result from design specification
obscurity, errors, omissions and changes ordered by client. This could be avoided through
the procurement of experienced architects and engineers from as early as the conceptual
phase. To achieve effective design, objectives must be clearly presaged by the client to the
designer at the conceptual phase, ensuring that client requirements are met while still
maintain timely project delivery.
This study showed fluctuation in construction as a top effect of increase in the cost of
building on housing delivery. In order to diminish excessive fluctuation in the cost of
construction, Desai and Desale (2013) suggested that stakeholders should have a well-
developed plan for materials, in advance, to avoid the effect of increase in building materials
prices in the market. Thus proper planning and scheduling at the initial stages of
construction is essential; this includes early purchase of building materials within the
budgeted cost and suitable storage of building materials to avoid cost overrun, disputes and
inflation. This will enhance timely delivery of housing at the budgeted cost while meeting
client expectations.
The delivery of sustainable housing entails the ability to meet the present housing needs of
humans without obliging on the capacity of the future generation to meet their own needs.
Hence, the enhancement requires major resources (materials, machinery and manpower),
and criteria carefully considered by construction stakeholders for a successful project
delivery. Proficient consideration of several criteria in material selection will ensure
sustainable development in building design and construction. Maintenance cost, energy
consumption and maintainability are significant criteria to be considered in the selection of
sustainable building materials to enhance delivery of affordable housing. Thus, effective
consideration of building materials before selection in construction towards enhancing
sustainable housing delivery based on socio-economic, environmental and technical criteria
is a framework to ensure that sustainability supply chain requirements are met from the very
beginning of the project.
The study concluded that proper consideration of these findings obtained in the study will aid
the development of the framework, presented in Figure 4.6, as an advantageous model to be
operationalised on Western Cape construction sites. Adequate application of the
recommendations presented in this study will significantly enhance sustainable housing
delivery that is cost-efficient, at expected qualities, within a specified time and affordable.
107
5.6 Areas for further study
This research study recommends, among other issues, to search and develop new
sustainable building materials and technologies applicable to the South African construction
industry.
108
REFERENCES
Abdul-Rahman, H. & Alidrisyi, M.N. 1994. A perspective of material management practices
in a fast developing economy: the case of Malaysia. Construction Management and
Economics, 12(5):413-422.
Abdul-Rahman, H., Wang, C. & Yap, J.B.H. 2015. Impacts of design changes on
construction project performance: Insights from a literature review. In 14th Management In
Construction Research Association (MiCRA 2015) Annual Conference and General Meeting.
Abeysundara, U. G., Babel, S. & Gheewala, S. 2009. A matrix in life cycle perspective for
selecting sustainable materials for buildings in Sri Lanka. Building and Environment, 44(5):
997-1004.
Abidin, N.Z., 2010. Investigating the awareness and application of sustainable construction
concept by Malaysian developers. Habitat International, 34(4), pp.421-426.
Achuenu, E. & Ujene, A. O. 2006. Evaluation of Labour and Material Costs in Building
Elements in Nigeria. Nigerian Journal of Construction Technology and Management. 7(1):
99-110.
Adamu, P.A., 2013. THE INFLATION AND ECONOMIC GROWTH NEXUS IN ECOWAS
COUNTRIES: AN EMPIRICAL INVESTIGATION. West African financial and Economic
review, p.31.
Adebowale, O.J., 2014. Framework for effective management of the construction workforce
towards enhancement of labour efficiency during the building production process in South
Africa (Doctoral dissertation, Cape Peninsula University of Technology).
.
Adedeji, Y.M.D. 2012. Sustainable housing provision: preference for the use of interlocking
masonry in housing delivery in Nigeria. Architecture Research, 2(5):81-86.
Adekoya, S. O. 2003. Housing development in Nigeria, which way forward. The Professional
Builders, 4:29.
109
Ade-ojo, C. & Babalola, A. 2013. Cost and Time Performance of Construction Projects under
Due Process Reform in Nigeria. International journal of Engineering and Science, 3(6):1-6.
Adlers, S. & Clark, R. 2008. How it’s done - An invitation to social research. 3rd ed.
Thompson Wadsworth, 216-244.
Agapiou, A., Clausen, L.E., Flanagan, R., Norman, G. & Notman, D. 1998. The role of
logistics in the materials flow control process. Construction Management & Economics,
16(2):131-137.
Agene, C.E. 1991. Foreign exchange and international trade in Nigeria. Gene publications.
Aibinu, A.A. & Jagboro, G.O. 2002. The effects of construction delays on project delivery in
Nigerian construction industry. International Journal of Project Management, 20(8):593-599.
Akadiri, P.O. 2011. Development of a multi-criteria approach for the selection of sustainable
materials for building projects. Unpublished PhD thesis Dissertation, University of
Wolverhampton, Wolverhampton.
Akadiri, P.O. and Olomolaiye, P.O., 2012. Development of sustainable assessment criteria
for building materials selection. Engineering, Construction and Architectural Management,
19(6), pp.666-687.
Akadiri, P.O., Chinyio, E.A. and Olomolaiye, P.O., 2012. Design of a sustainable building: A
conceptual framework for implementing sustainability in the building sector. Buildings, 2(2),
pp.126-152.
Akanni, P.O., Oke, A.E. and Omotilewa, O.J., 2014. Implications of Rising Cost of Building
Materials in Lagos State Nigeria. SAGE Open, 4(4), p.2158244014561213.
Alarcon, L. F. 1994. Tools for the identification and reduction of waste in construction
projects. Lean construction, Rotterdam, 365-377.
Al-Dubaisi, A.H., 2000. Change orders in construction projects in Saudi Arabia. Unpublished
MS Thesis, King Fahd University of Petroleum and Minerals, Dhahran, Saudi Arabia.
110
Al-Juwairah, Y. 1997. Factors Affecting Construction Costs in Saudi Arabia. Unpublished
Master’s thesis, King Fahd University of Petroleum and Minerals, Dhahran, Saudi Arabia.
Ali, A.S. & Kamaruzzaman, S.N. 2010. Cost performance for building construction projects in
Klang Valley. Journal of Building Performance, 1(1).
Alibaba, H.Z. and Özdeniz, M.B., 2004. A building elements selection system for architects.
Building and Environment, 39(3), pp.307-316.
Alsuliman, J., Bowles, G. & Chen, Z. 2012. Current practice of variation order management
in the Saudi construction industry. Association of Researchers in Construction Management,
1-10.
Aluko O.O. 2008. Construction project abandonment in Nigeria: A Threat to National
Economy, Knowledge Review, 16(3):18-23.
Amaratunga, D., Baldry, D., Sarshar, M. & Newton, R. 2002. Quantitative and qualitative
research in the built environment: application of “mixed” research approach. Work study,
51(1):17-31.
Ameh, O.J. & Osegbo, E.E. 2011. Study of relationship between time overrun and
productivity on construction sites. International Journal of Construction Supply Chain
Management, 1(1):56-67.
Anderson, S., Bennett, R. & Collopy, C. 2000. G-rated: Assessing the NEED for GREEN
building design and construction sector survey results. Office of Sustainable Development–
Green Building Division, Portland, Oregon.
Angelo, W.J. & Reina, P. 2002. Megaprojects need more study up front to avoid cost
overruns. ENR, 249(3).
Anosike, P. 2009. Nigerian groans under high cost of building material. The Daily Sun, 38-
39.
Arora, P., 2009. Analysis of selection criteria for green building materials in Rinker Hall.
111
Arnold, J.R & Chapman. 2004. Introduction to Materials Management 5th Ed., New Jersey:
Prentice-Hall.
Asif, M., Bruijn, E.J., Fisscher, O.A.M & Steenhuis, H.J. 2008. Achieving Sustainability Three
Dimensionally. Proceedings of the 2008 IEEE, ICMT: 423-28.
Assaf, S.A. & Al-Hejji, S. 2006. Causes of delay in large construction projects. International
Journal of Project Management, 24(4):349-357.
Ayodele, E. O., & Alabi, O. M. 2011. Abandonment of construction projects in Nigeria:
Causes and effects. Journal of Emerging Trends in Economics and Management Sciences,
2:142-145
Azhar, N., Farooqui, R.U. & Ahmed, S.M, 2008. Cost overrun factors in construction industry
of Pakistan. In First International Conference on Construction in Developing Countries
(ICCIDC–I), Advancing and Integrating Construction Education, Research & Practice, 499-
508.
Azis, A.A.A, Memon, A.H., Rahman, I.A. & Abdullah. M.R. 2013. Controlling Cost Overrun
Factors in Construction Projects in Malaysia: Research Journal of Applied Science
Engineering and Technology, 5(8):2621-2
Azmy, N. 2012, The role of team effectiveness in construction project teams and project
performance, Iowa State University.
Babbie, E. R. 1990. Survey research methods, Belmont, California, Wadsworth Pub. Co.
Babbie, E. 2007. The practice of social research. 11th ed. Thompson Wadsworth, 102-325.
Babbie, E. and Mouton, J., 2005. Qualitative studies. The practice of social research,
pp.269-311.
Bainbridge, D.A., 2004. Sustainable building as appropriate technology. Building without
Borders: Sustainable Construction for the Global Village, 55-84.
112
Bakhtiar, K.A., Shen, L.Y., & Misnan, S.H. 2008. A framework for comparison study on the
major methods in promoting sustainable construction practice. Journal Alam Bina.Jilid.
12(3):55-69.
Bal, M., Bryde, D., Fearon, D., & Ochieng, E. 2013. Stakeholder engagement: Achieving
sustainability in the construction sector. Sustainability, 5(2):695-710.
Baloi, D. 2003. Sustainable construction: challenges and opportunities. In: Greenwood, D J
(Ed.), 19th Annual Association of Researchers in Construction Management (ARCOM)
Conference, 3-5 September 2003. University of Brighton, (1):289-97.
Baloyi, L. & Bekker, M. 2011. Causes of construction cost and time overruns: The 2010 FIFA
World Cup stadia in South Africa. Acta Structilia, 18(1):51-67.
Barbour, R. 2008. Introducing qualitative research – A student guide to the craft of doing
qualitative research, Sage publications, 61-74.
Beder, S. 1996. The nature of sustainable development. Newham, Australia: Scribe
Publications.
Berggren, B. 1999. Industry's contribution to sustainable development, in Building Research
and Information, 27(6):432-436.
Biggam, J. 2015. Succeeding with your master's dissertation: a step-by-step handbook.
McGraw-Hill Education (UK).
Bovea, M.D. & Gallardo, A. 2006. The influence of impact assessment methods on materials
selection for eco-design. Materials & Design, 27(3):209-215.
Bragança, L., Koukkari, H., Blok, R., Gervásio, H., Veljkovic, M., Plewako, Z., Landolfo, R.,
Ungureanu, V. & Silva, L.S.D. 2007, September. Sustainability of constructions: integrated
approach to life-time structural engineering: proceedings of the 1st workshop of the COST
Action C25. In Sustainability of constructions: integrated approach to life-time structural
engineering: proceedings of the 1st workshop of the COST Action C25, 1-354.
.
Bryman, A. 2004. Social research methods. 2nd ed., Oxford University press, 10-341.
113
Bryman, A. 2012. Social research methods, 4th ed., Oxford University Press: New York,
133,
Bryman A. & Bell, E. 2015. Business Research Methods, 4th ed., Oxford University Press,
27.
Burns, R. 2000. Introduction to research method, 2nd ed. Sage publication, 35-84.
Castillo, R. and Chung, N.C., 2004. The value of sustainability, CIFE (Centre for Integrated
Facility Engineering) Working Paper 091, Stanford University. Available at
www.stanford.edu/group/CIFE/online.publications/WP091.pdf [accessed on Feb. 12, 2017].
Chan, F.T.S. 2002. Design of material handling equipment selection system: an integration
of expert system with analytic hierarchy process approach. Integrated Manufacturing
Systems, 13(1):58-68.
Chan, A.P. & Chan, A.P. 2004. Key performance indicators for measuring construction
success. Benchmarking: an international journal, 11(2):203-221.
Chan, S. L., & Park, M. 2005. Project Cost Estimation using principal component regression.
Construction Management and Economics, 23(3):295-304.
Che Wan Putra, C.W.F., Ahmad, A., AbdMajid, M.Z. & Kasim, N. 1999. Improving material
scheduling for the construction industry in Malaysia. In: Malaysian Science and Technology
Congress 99, 6-8 December 1999. Malaysia.
Chitkara, K. K. 2006. Construction Project Management, Planning, Scheduling and
Controlling. New Delhi: Tata McGraw-Hill Publishing Company Limited.
Choguill, C.L. 1996. Ten steps to sustainable infrastructure. Habitat International, 20(3):389-
404.
Choudhury, I. & Rajan, S. 2003. Time-cost relationship for residential construction in Texas,
A & M University college station, Texas, 1-7.
114
Cidb. 2011. The Building and Construction Materials Sector, Challenges and Opportunities.
Pretoria: cidb.
Cohen, L., Manion, L. and Morrison, K., 2013. Research methods in education. Routledge.
Cohn, R. & Ralston. 2005. Teamwork: Fad or Forever Article, Construction Executive, 4(5).
Construction Industry Development Board (CIDB). 2004. SA Construction Industry Status
Report – 2004: Synthesis review on the South African Construction Industry and its
Development. Discussion Document, CIDB, Pretoria
Creswell, J.W. 2009. Research design: qualitative, quantitative and mixed method
approaches. 3rd ed., Los Angeles, Sage.
Creswell, J.W. & Clark, V.L.P. 2007. Designing and conducting mixed methods research.
da Rocha, C.G. and Sattler, M.A., 2009. A discussion on the reuse of building components in
Brazil: An analysis of major social, economical and legal factors. Resources, Conservation
and Recycling, 54(2), pp.104-112
Dahlberg, L. & McCaig, C. eds. 2010. Practical research and evaluation: a start-to-finish
guide for practitioners. Sage.
Dai, J., Goodrum, P.M. & Maloney, W.F. 2009. Construction craft workers’ perceptions of the
factors affecting their productivity. Journal of Construction Engineering and Management,
135(3):217-226.
Deng, Y.M. & Edwards, K.L. 2007. The role of materials identification and selection in
engineering design. Materials & design, 28(1):131-139.
Dey, P.K. 2001. Managing Projects in Fast Track – A Case of Public Sector 194
Organization in India. International Journal of Public Sector Management. 13(7): 588- 609.
Diesendorf, M. 2000. Sustainability and Sustainable development, in Dunphy, D.,
Benveniste, J., Griffiths, A. & Sutton, P. (eds.) Sustainability: The corporate challenge of the
21st century, Sydney, Allen & Unwin:19-37.
115
Ding, G.K., 2008. Sustainable construction: the role of environmental assessment tools.
Journal of environmental management, 86(3):451-464.
Ding, L., Quercia, R., Li, W. and Ratcliffe, J., 2011. Risky borrowers or risky mortgages
disaggregating effects using propensity score models. Journal of Real Estate Research,
33(2), pp.245-277.
Dlakwa, M.M. & Culpin, M.F., 1990. Reasons for overrun in public sector construction
projects in Nigeria. International Journal of Project Management, 8(4):237-241.
Doloi, H. 2013. Cost overruns and failure in project management: understanding the roles of
key stakeholders in construction projects. Journal of construction engineering and
management, 139(3): 267-279.
Donyavi, S. & Flanagan, R., 2009. The impact of effective material management on
construction site performance for small and medium sized construction enterprises. In
Proceedings of the 25th Annual ARCOM Conference, Nottingham, UK, 11-20.
Donyavi, S. & Flanagan, R. 2011. Tracking and positioning technology and its applications
for supply chain materials for small and medium enterprises (SMEs) on construction sites In:
Egbu, C. and Lou, E.C.W. (Eds.) Procs 27th Annual ARCOM Conference, 5-7 September
2011, Bristol, UK, Association of Researchers in Construction Management, 465-473.
Donald, G. 2005. Inflation and its eon Investment. Retrieved from
www.political.economy.com, accessed February 2017.
Du Plessis, C. 2002. Agenda 21 for sustainable construction in developing countries. CSIR
Report BOU E, 204.
Du Plessis, C. 2007. A Strategic Framework for Sustainable Construction in Developing
Countries. Construction Management and Economics, 25: 67-76.
Durdyev, S., Ismail, S., Bakar, N.A., Rizwan, M.S., Iqbal, M.J., Tan, F.Y., Yahya, K.K.,
Izvercian, M., Ivascu, L., Miclea, S. & Izvercianu, M. 2012. Factors Constraining Labour
Productivity: Case Study of Turkmenistan. International Proceedings of Economics
Development and Research, 55(1):1-5.
116
Dzeng, R.J. & Wu, J.S. 2012. The cost efficiency of construction industry in Taiwan. Open
Construction and Building Technology Journal, 6:8-16.
Easterby-Smith, M., Thorpe, R. & Jackson, P.R. 2012. Management Research. Sage.
Ebsen, C & Ramboll, B. 2000. International review of low-cost sustainable housing projects.
Proceedings: Strategies for a Sustainable built environment.
Elhag, T.M.S., Boussabaine, A.H. & Ballal, T.M.A. 2005. Critical determinants of construction
tendering costs: Quantity surveyors’ standpoint. International Journal of Project
Management, 23(7):538-545.
Elinwa, A.U. & Buba, S.A. 1993. Construction cost factors in Nigeria. Journal of Construction
Engineering and Management, 119(4):698-713.
Enshassi, A., Mohamed, S., Mustafa, Z.A. & Mayer, P.E, 2007. Factors affecting labour
productivity in building projects in the Gaza Strip. Journal of Civil Engineering and
Management, 13(4):245-254.
Enshassi, A., Al-Najjar, J. & Kumaraswamy, M. 2009. Delays and cost overruns in the
construction projects in the Gaza Strip. Journal of Financial Management of Property and
Construction, 14(2):126-151.
Esohofonie, F. P. 2008. Factors Affecting Cost of Construction in Nigeria. Unpublished
Master’s Dissertation, University of Lagos, Nigeria.
EU Framework. 1998. Understanding and Monitoring the Cost-Determining Factors of
Infrastructure Projects A User's Guide. Accessed February, 2017,
http://ec.europa.eu/regional_policy/sources/docgener/evaluation/pdf/5_full_en.pdf
Everett, A. & Barritt, C.M.H. 1994. Materials (Mitchells Building Series).
Fapohunda, J.A. & Omoniyi, S.S. 2011. Enhancement of site managers’ efficiency towards
accomplishments of project objectives. Organization, Technology & Management in
Construction: An International Journal, 3(2):308-316.
117
Faremi, O., Adenuga, O., Dada, M. & John, B. 2015. Factors affecting maintenance cost of
institutional buildings. In 9th Unilag Annual Research Conference & Fair on Health,
Infrastructure and Development, University of Lagos.
Fellows, R.F. & Liu, A.M. 2008. Research methods for construction. John Wiley & Sons.
Ferreira, K. 2007. First steps in research, Van Schaik publishers, 99-117.
Fichtner, P. 2011. Inflation and Solvency Models – Are We Missing Something? available:
www.deloitte.com/assets/.../ch_en_Inflation_Solvency_Models.pdf [accessed on: 8
December 2016].
Flick, U. 2015. Introducing research methodology: A beginner's guide to doing a research
project. Sage.
Flórez, L., Castro, D. and Irizarry, J., 2010. Impact of Sustainability Perceptions on Optimal
Material Selection in Construction Projects. In Proceedings of the Second International
Conference on Sustainable Construction Materials and Technologies (pp. 719-727).
Flowers, P. 2009. Research Philosophies–Importance and Relevance', Research Leading
Learning and Change-Cranfield School of Management, 1.
Flyvbjerg, B., Skamris Holm, M.K. & Buhl, S.L. 2003. How common and how large are cost
overruns in transport infrastructure projects? Transport reviews, 23(1):71-88.
Folorunso, C.O., Akingbohungbe, D.O. & Ogunruku, M.P. 2017. Choice Prediction Factors in
Building Exterior Finishes’ Selection in Lagos, Nigeria: Clients’ Perspective.
Formoso, C.T., Isatto, E.L. & Hirota, E.H. 1999, July. Method for waste control in the building
industry. In Proceedings IGLC (7):325.
Fowler Jr, F.J. & Cosenza, C. 2009. Design and evaluation of survey questions. The SAGE
handbook of applied social research methods, 375-412.
118
Frimpong, Y., Oluwoye, J. & Crawford, L. 2003. Causes of delay and cost overruns in
construction of groundwater projects in a developing countries; Ghana as a case study.
International Journal of project management, 21(5):321-326.
Froeschle, L.M. 1999. Environmental assessment and specification of green building
materials. Construction Specifier, 52:53-57.
Ganiyu, B.O. 2016. Strategy to enhance sustainability in affordable housing construction in
South Africa (Doctoral dissertation, Cape Peninsula University of Technology).
Gann, D.M. & Salter, A.J. 2000. Innovation in project-based, service-enhanced firms: the
construction of complex products and systems. Research policy, 29(7):955-972.
Gibberd, J. 2005. Assessing sustainable buildings in developing countries –The Sustainable
Building Assessment Tool (SBAT) and the Sustainable Building Lifecycle (SBL).
Proceedings of the 2005 World Sustainable Building Conference, 27-29 September. Tokyo:
1605-1611.
Girden, E. R. & Kabacoff, R. I. 2011. Evaluating research articles: from start to finish – 3rd
ed. Los Angeles: Sage Publications Ltd.
Goddard, W., & Melville, S. 2004. Research methodology: An introduction. Juta and
Company Ltd. for science and engineering students. Juta & Co Ltd, Cape Town, South
Africa.
Godfaurd, J., Clements-Croome, D. and Jeronimidis, G., 2005. Sustainable building
solutions: a review of lessons from the natural world, Building and Environment, 40(3), pp.
28-319.
Goldkuhl, G. 2012. Pragmatism vs. interpretivism in qualitative information system research,
European. Journal of information system, 1-19.
Gulghane, A.A. & Khandve, P.V. 2015. Management for Construction Materials and Control
of Construction Waste in Construction Industry: A Review. Int. Journal of Engineering
Research and Applications, 5(4):59-64.
119
Hanna, A.S., Taylor, C.S. & Sullivan, K.T. 2005. Impact of extended overtime on
construction labor productivity. Journal of construction engineering and management,
131(6):734-739.
Harman. J. 2007. Construction industry could be next victim of climate change.
Haseeb, M., Lu, X., Hoosen, A.B. & Rabbani, W. 2011. Causes and effects of delays in large
construction projects of Pakistan. Kuwait Chapter of Arabian Journal of Business and
Management Review, 1(4):18-42.
Henn, M., Weinstein, M. & Foard, N. 2006. A short introduction to social research. Sage
publications, 3-206.
Hill, R. C., & Bowen, P. A. 1997. Sustainable construction: principles and a framework for
attainment. Construction Management & Economics, 15(3):223-239.
Hong Kong Environmental Protection Department. (2010). Monitoring solid waste in Hong
Kong: waste statistics for 2010. (Accessed 21 September, 2016). Available at
https://www.wastereduction.gov.hk/en/materials/info/msw2010.pdf
Ibn-Homaid, N.T. 2002. A comparative evaluation of construction and manufacturing
materials management. International Journal of Project Management, 20(4):263-270.
Idoro, G. I., & Jolaiya, O. 2010. Evaluating material storage strategies and their relationship
with construction project performance. Proceedings of CIB International Conference on
Building Education and Research, University of Cape Town, 103-110.
Ihuah, P.W. 2015. Building materials costs increases and sustainability in real estate
development in Nigeria. African Journal of Economic and Sustainable Development,
4(3):218-233.
Ihuah, P.W., Kakulu, I.I. & Eaton, D. 2014. A review of Critical Project Management Success
Factors (CPMSF) for sustainable social housing in Nigeria. International Journal of
Sustainable Built Environment, 3(1):62-71.
120
Isa, N. K. M., Alias, A., & Abdul Samad, Z. 2014. Sustainability integration into building
projects: Malaysian construction stakeholders' perspectives. The Macrotheme Review,
3(3):14-34.
Iwaro, J. & Mwasha, A. 2012. The effects of ISO certification on organization workmanship
performance. The Quality Management Journal, 19(1):53.
Iyer, K.C. & Jha, K.N. 2005. Factors affecting cost performance: evidence from Indian
construction projects. International journal of project management, 23(4):283-295.
.
Iyoha, M.A., Oyefusi, S.A. & Oriakhl, D.E. 2003. An Introduction to Modern Macroeconomics
Benin.
Jagboro, G.O. & Atigogo, M.E. 2000. Linkage between Share Prices of Construction Firms
and Foreign Exchange. The Nigerian Experience African Journal of Business & Research,
1(2).
Jagboro, G.O. & Owoeye, C.O. 2004. A model for predicting the prices of building materials
using the exchange rate in Nigeria. The Malaysian Surveyor, 5(6):9-14.
James, P.R., Pell, E., Sweeney, C. & John-Cox, C.S. 2006. Review of plasterboard material
flows and barriers to greater use of recycled plasterboard. The Waste & Resources Action
Programme.
Jari, A.J. & Bhangale, P.P. 2013. To study critical factors necessary for a successful
construction project. International Journal of Innovative Technology and Exploring
Engineering, 2(5):331-335.
Jarkas, A.M. & Radosavljevic, M. 2012. Motivational factors impacting the productivity of
construction master craftsmen in Kuwait. Journal of Management in Engineering, 29(4):446-
454.
John, G., Clements-Croome, D. & Jeronimidis, G. 2005. Sustainable building solutions: a
review of lessons from the natural world. Building and environment, 40(3):319-328.
121
Johnson, R.B., Onwuegbuzie, A.J. & Turner, L.A. 2007. Toward a definition of mixed
methods research. Journal of mixed methods research, 1(2):112-133.
Kaming, P.F., Olomolaiye, P.O., Holt, G.D. & Harris, F.C. 1997. Factors influencing
construction time and cost overruns on high-rise projects in Indonesia. Construction
Management & Economics, 15(1):83-94.
Kasim, N., 2011. ICT implementation for materials management in construction projects:
case studies. Journal of Construction Engineering and Project Management, 1(1), pp.31-36
Kasim, N.B., Anumba, C.J. & Dainty, A.R.J. 2005, September. Improving materials
management practices on fast-track construction projects. In 21st Annual ARCOM
Conference, SOAS, University of London (2):793-802.
Kasimu, M.A. 2012. Significant factors that cause cost overruns in building construction
project in Nigeria. Interdisciplinary journal of contemporary research in business, 3(11):775-
780.
Karana, E., Hekkert, P. & Kandachar, P. 2010. A tool for meaning driven materials selection.
Materials & Design, 31(6):2932-2941.
Kareem, K.R. & Pandey, R.K. 2013. Study of Management and Control of Waste
Construction Materials in Civil Construction Project. International Journal of Engineering and
Advanced Technology, 2(3).
Kerzner, H. 2013. Project management: a systems approach to planning, scheduling, and
controlling. John Wiley & Sons.
Kibert, C.J. 2012. Sustainable construction: green building design and delivery. John Wiley &
Sons.
Kim, J. J. & Rigdon, B. 1998. Sustainable Architecture Module: Qualities, Use, and
Examples of Sustainable Building Materials. National Pollution Prevention Centre for Higher
Education: pp. 1-44.
122
Knutson, K., Schexnayder, J., Fiori, C. & Mayo, E. 2009. Construction management
fundamentals. 2nd ed. McGraw-Hill, 25-50.
Koskela, L.J. & Howell, G. 2001, August. Reforming project management: the role of
planning, execution and controlling. In Proceedings of 9th International Group for Lean
Construction Conference: 185-198.
Kumar, R. 2011. Research methodology – A step by step guide for beginners, 3rd ed. Sage
publications, 11-199.
Kunzlik, P. 2003. The environmental performance of public procurement: issues of policy
coherence. In N. Johnstone (editor), 1st edition, Organisation for Economic Cooperation and
Development, Paris: 157–235.
Lam, P. T., Chan, A. P., Wong, F. K., & Wong, F. W. 2007. Constructability rankings of
construction systems based on the analytical hierarchy process. Journal of Architectural
Engineering, 13:36-43.
Lambropoulos, S. 2007. The use of time and cost utility for construction contract award
under European Union Legislation. Building and Environment, 42(1):452-463.
Leedy, P. & Ormrod, J. 2010. Practical Research planning and design 9th edition Boston:
Pearson Education International.
Le-Hoai, L., Dai Lee, Y. & Lee, J.Y. 2008. Delay and cost overruns in Vietnam large
construction projects: A comparison with other selected countries. KSCE journal of civil
engineering, 12(6):367-377.
Lim, S. K., & Yang, J. 2008. Understanding the need of project stakeholders for improving
sustainability outcomes in infrastructure projects. In Proceedings of the Performance and
Knowledge Management Joint CIB Conference (pp. 332-343).
Lindén, S. & Josephson, P.E. 2013. In-housing or out-sourcing on-site materials handling in
housing? Journal of Engineering, Design and Technology, 11(1):90-106.
Ljungberg, L.Y. 2007. Materials selection and design for development of sustainable
products. Materials & Design, 28(2):466-479.
123
Love, P. E. D., Holt, G. D., Shen, L. Y., Li, H. & Irani, Z., 2002. Using systems dynamics to
better understand change and rework in construction project management systems.
International Journal of Project Management, 20: pp 425 - 436.
Lu, W., & Tam, V. W. 2013. Construction waste management policies and their effectiveness
in Hong Kong: A longitudinal review. Renewable and Sustainable Energy Reviews, 23, 214
223.
Mahamid, I. & Bruland, A., 2012. Cost deviation in road construction projects: The case of
Palestine. Australasian Journal of Construction Economics and Building, 12(1):58.
Makulsawatudom, A., Emsley, M. & Sinthawanarong, K. 2004. Critical factors influencing
construction productivity in Thailand. The journal of KMITNB, 14(3):1-6.
Mallak, L.A., Patzak, G.R. & Kurstedt, H.A. 1991. Satisfying stakeholders for successful
project management. Computers & industrial engineering, 21(1-4):429-433.
Manavazhi, M.R. & Adhikari, D.K. 2002. Material and equipment procurement delays in
highway projects in Nepal. International Journal of Project Management, 20(8):627-632.
Mansfield, N.R., Ugwu, O.O. & Doran, T. 1994. Causes of delay and cost overruns in
Nigerian construction projects. International Journal of Project Management, 12(4):254-260.
Maree, K. 2007. First steps in research. Van Schaik Publishers.
Maree, K. and Pietersen, J., 2007. The quantitative research process. First steps in
research. Pretoria: Van Schaik, pp.144-153.
Mbachu, J.I.C. & Nkado, R.N. 2004. Reducing building construction costs; the views of
consultants and contractors. In Proceedings of the International Construction Research
Conference of the Royal Institution of Chartered Surveyors, Leeds Metropolitan University.
McElroy, B. & Mills, C. 2000. “Managing stakeholders”. In Gower Handbook of Project
Management Edited by: Turner, R. J and Sinister, S. J. 3rd Edition, Gower Publishing
Limited, Aldershot:757-75.
124
McNiff, J. & Whitehead, J. 2011. All you need to know about action research. Sage
Publications.
McQueen, R.A. & Knussen, C. 2002. Research methods for social science: A practical
introduction. Pearson Education.
Memon, A.H., Rahman, I.A., Abdullah, M.R. & Azis, A.A.A. 2011. Factors affecting
construction cost in Mara large construction project: perspective of project management
consultant. International Journal of Sustainable Construction Engineering and Technology,
1(2):41-54.
Menassa, C. C., & Baer, B. 2014. A framework to assess the role of stakeholders in
sustainable building retrofit decisions. Sustainable Cities and Society, 10:207-221.
Meryman, H. & Silman, R. 2004. Sustainable engineering - using specifications to make
it happen. Structural Engineering International (IABSE, Zurich, Switzerland), 14(3):216-219.
Mojekwu, J.N., Idowu, A. and Sode, O., 2013. Analysis of the contribution of imported and
locally manufactured cement to the growth of gross domestic product (GDP) of Nigeria
(1986-2011). African Journal of Business Management, 7(5), p.360.
Monye-Emina, A. I. 2007. Determinants of inflation in Nigeria: Empirical Evidence from the
estimation of an error-correction model. Journal of Economic Studies, 6(1):7-10.
Morton, R. 2002. Construction UK: Introduction to the Industry. Oxford. Blackwell.
Munasinghe, M., 1994. Sustainomics: a transdisciplinary framework for sustainable
development. In Keynote Paper, Proc. 50th Anniversary Sessions of the Sri Lanka Assoc. for
the Adv. of Science.
Mustapa, M. & Rashid, R. 2012. The challenges of managing people in construction. 1-12.
Nagapan, S., Abdul Rahman, I. and Asmi, A., 2011. A review of construction waste cause
factors.
125
Nagapan, S., Rahman, I.A., Asmi, A., Memon, A.H. & Latif, I. 2012, December. Issues on
construction waste: the need for sustainable waste management. In Humanities, Science
and Engineering (CHUSER), 2012 IEEE Colloquium on (325-330). IEEE.
Nassar, K., Thabet, W. & Beliveau, Y. 2003. A procedure for multi-criteria selection of
building assemblies. Automation in Construction, 12(5):543-560.
National Treasury. 2012. National Treasury PPP Manual. National Treasury, Pretoria.
Nega, F. 2008. Causes and effects of cost overrun on public building construction projects in
Ethiopia. Unpublished doctoral dissertation, Addis Ababa University, Ethiopia.
Neuman, L.W. 2002. Social research methods: Qualitative and quantitative approaches.
Nieuwenhuis, J., 2007. Qualitative research designs and data gathering techniques. First
steps in research, 69-97.
Niu, J.L. & Burnett, J. 2001. Setting up the criteria and credit-awarding scheme for building
interior material selection to achieve better indoor air quality. Environment international,
26(7):573-580.
Obadan, M.I. 2001. Poverty reduction in Nigeria: The way forward. CBN Economic and
Financial Review, 39(4):159-188.
Ofori, G. 1999, September. Satisfying the customer by changing production patterns to
realise sustainable construction. In Proceedings, Joint Triennial Symposium of CIB
Commissions W65 and (55):41-56.
Ofori, G. & Kien, H. L. 2004. Translating Singapore architects’ environmental awareness into
decision making. Building Research and Information, 32(1):27-37.
Oghenekevwe, O., Olusola, O. & Chukwudi, U.S. 2014. An assessment of the impact of
inflation on construction material prices in Nigeria. PM World Journal, 3(4):1-22.
126
Ogunlana, S.O., Promkuntong, K. & Jearkjirm, V. 1996. Construction delays in a fast-
growing economy: comparing Thailand with other economies. International journal of project
Management, 14(1):37-45.
Ogunsemi, D.R. 2010. The use of enough quality and quantity materials for building a
durable edifice. A Lecture delivered at Campus Transformation Network, Federal University
of Technology.
Ogunsemi, D.R. & Aje, I.O., 2006. A model for contractors’ selection in Nigeria. Journal of
Financial management of Property and Construction, 11(1):33-44.
Olabosipo, F., Ayodeji, O. & James, O. 2011. Factors affecting the performance of labour in
Nigerian construction sites. Mediterranean journal of social science, 2(2):251-257.
Oladipo, F.O. & Oni, O.J. 2012. Review of Selected Macroeconomic Factors Impacting
Building Material Prices in Developing Countries–A Case of Nigeria. Ethiopian Journal of
Environmental Studies and Management, 5(2):131-137.
Olawale, Y.A. & Sun, M. 2010. Cost and time control of construction projects: inhibiting
factors and mitigating measures in practice. Construction Management and Economics,
28(5):509-526.
Olayinka, R.A.2015. A Knowledge Management Framework for Reducing the Cost of Poor
Quality on Construction Projects. Unpublished PhD Thesis University of Wolverhampton,
Wolverhampton.
O'Leary, Z. 2017. The essential guide to doing your research project. Sage.
Ortiz, O., Castells, F. & Sonnemann, G. 2009. Sustainability in the construction industry: A
review of recent developments based on LCA. Construction and Building Materials,
23(1):28-39.
Oyedele, O. & Tham, W. 2006. Client’s assessment of architects’ performance in building
delivery process: evidence from Nigeria. Journal of building and environment, 2090-2099.
127
Oyediran, S.O. 2006, October. Modeling inflation dynamics in the construction sector of a
developing economy. In Shaping the Change XXIII FIG Congress, Munich, Germany.
Oyewobi, L.O., Ibironke, O.T., Ganiyu, B.O. & Ola-Awo, A.W., 2011. Evaluating rework cost-
A study of selected building projects in Niger State, Nigeria. Journal of Geography and
Regional Planning, 4(3):147.
Patel, K.V. & Vyas, C.M. 2011, May. Construction material management on project sites. In
National Conference on Recent Trends in Engineering & Technology, 1-5.
Perkins, D. F., Feinberg, M. E., Greenberg, M. T., Johnson, L. E., Chilenski, S.
M.,Mincemoyer, C. C., & Spoth, R. L. 2011. Team factors that predict sustainability
indicators for community-based prevention teams. Evaluation and program planning,
34(3):283-291.
Pinder, J., III, R.S. and Saker, J., 2013. Stakeholder perspectives on developing more
adaptable buildings. Construction Management and Economics, 31(5), pp.440-459.
Polat, G. & Ballard, G. 2004, August. Waste in Turkish construction: need for lean
construction techniques. In Proceedings of the 12th Annual Conference of the International
Group for Lean Construction IGLC-12, August, Denmark, 488-501.
Prajapati,S.K , Gupta, K & Pandey, M., 2016. Causes and Effects of Cost Overrun On
Construction Projects in Madhya Pradesh. International Journal of Engineering Development
and Research, 1346-1350.
Project Management Body of Knowledge (PMBOK® GUIDE). 2008. In Project Management
Institute. Public Finance Management Act. 1999. Available Online:
http://www.treasury.gov.za/legislation/PFMA/act.pdf (accessed March, 2017).
Quartaroli, M. & Lapan, S. 2009. Research essentials – An introduction to design and
practices, 1st ed. Jossey-Bass, 75-87.
Rajaprabha, R., Velumani, P. & Jayanthi, B. 2016. Factors Affecting the Cost of Building
Material in Construction Projects. International Journal of Science and Engineering
Research, 4(4):1-6.
128
Ramabodu, M.S. & Verster, J.J.P, 2010, July. Factors contributing to cost overruns of
construction projects. In Proceeding of the 5th Built Environment Conference, 131-143.
Rao, R.V. 2008. A decision making methodology for material selection using an improved
compromise ranking method. Materials & Design, 29(10):1949-1954.
Reina, P. & Angelo, W.J., 2002. Megaprojects need more study up front to avoid cost
overruns. ENR, 249(3).
Rivas, R.A., Borcherding, J.D., González, V. & Alarcón, L.F. 2010. Analysis of factors
influencing productivity using craftsmen questionnaires: Case study in a Chilean construction
company., 137(4):312-320.
Robichaud, L. B., & Anantatmula, V. S. 2011. Greening project management practices for
sustainable construction. Journal of Management in Engineering, 27(1):48-57.
Rohracher, H. 2001. Managing the technological transition to sustainable construction of
buildings: a socio-technical perspective. Technology Analysis & Strategic Management,
13(1):137-150.
Rubin, R. & Babbie, E.R. 2010. Essential research methods for social work (2nd ed).
Belmont, CA: Brooks-Cole.
Rumane, R. 2011. Quality management in construction projects. Crc Press, 8-20.
Sambasivan, M. & Soon, Y.W. 2007. Causes and effects of delays in Malaysian construction
industry. International Journal of project management, 25(5):517-526.
Sanvido V, Grobler F, Parfitt K, & Guvenis M. 1992. Critical success factors for construction
projects. Journal of Construction Engineering and Management, ASCE; 118(1):94-111.
Shannon, C., 2005. “10 Criteria for Evaluating Green Building Materials.” Heartland Green
Sheets, School of Architecture and Urban Design, University of Kansas, KS.
http://www.heartlandgreensheets.org/10criteria.html#1 (accessed: May. 10, 2017).
Sharma, B. & Mehta, G., 2014. Selection of Materials for Green Construction: A Review.
129
Smith, J., Love, P. E., & Wyatt, R. 2001. To build or not to build? Assessing the strategic
needs of construction industry clients and their stakeholders. Structural Survey, 19(2), 121-
132
Soham, M. & Rajiv, B. 2013. Critical factors affecting labour productivity in construction
projects: case study of South Gujarat region of India. International Journal of Engineering
and Advanced Technology, 2(4):583-591.
Solanke, B.H. 2015. Effective strategy for construction materials procurement during
construction towards the enhancement of sustainable building production in Western Cape,
South Africa (Doctoral dissertation, Cape Peninsula University of Technology).
Son, H., Kim, C., Chong, W. K., & Chou, J. S. 2011. Implementing sustainable development
in the construction industry: constructors' perspectives in the US and Korea. Sustainable
Development, 19(5):337-347.
South Africa statistical release 2012. Quarterly labour force survey. Available
at: www.statssa.gov.za (Accessed: Oct. 4, 2016).
Steele, J. L. 2000. The Interdisciplinary Conceptual Design of Buildings, unpublished PhD
Dissertation, department of Civil and Building Engineering, Loughborough University, UK.
Stigson, B. 1999. Sustainable development for industry and society. Building Research &
Information, 27(6):424-430.
Storvang, P., & Clarke, A. H. 2014. How to create a space for stakeholders’ involvement in
construction. Construction Management and Economics, 32(12)1166-1182.
Struwig, M., Struwig, F.W. & Stead, G.B. 2001. Planning, reporting & designing research.
Pearson South Africa.
Swanson, R.A. & Holton, E.F. 2005. Research in organizations: Foundations and methods in
inquiry. Berrett-Koehler Publishers.
Takim, R. 2009. The Management of Stakeholders’ Needs and Expectations in the
Development of Construction Project in Malaysia. Modern Applied Science. 3(5): 167-175.
130
Tam, V.W. 2009. Comparing the implementation of concrete recycling in the Australian and
Japanese construction industries. Journal of Cleaner Production, 17(7):688-702.
Tam, V.W. & Tam, C.M. 2006. Evaluations of existing waste recycling methods: a Hong
Kong study. Building and Environment, 41(12):1649-1660.
Tam, W.Y.V., Tam, C.M. & Zeng, S.X .2007. Towards adoption of prefabrication in
construction. Build. Envrion, 42 (36):42-54.
Tavakol, M. & Dennick, R. 2011. Making sense of Cronbach’s alpha. International journal of
medical education, (2):53.
Taylor, G.D. 2013. Materials in construction: An introduction. Routledge.
Teddlie, C. & Tashakkori, A. 2009. Foundations of mixed methods research: Integrating
quantitative and qualitative approaches in the social and behavioral sciences. Sage.
Thomas, R.M., 2003. Blending qualitative and quantitative research methods in theses and
dissertations. Corwin Press.
Thomas, E.U & Martin L. 2004. Essentials of construction project management (first Ed.)
University of New South Wales Press Ltd., Australia.
Thomas, E. and Magilvy, J.K., 2011. Qualitative rigor or research validity in qualitative
research. Journal for specialists in pediatric nursing, 16(2), pp.151-155.
Treloar, G., Fay, R., Ilozor, B. & Love, P. 2001. Building materials selection: greenhouse
strategies for built facilities. Facilities, 19(3/4):139-150.
Tseng, M.L., Lin, Y.H. & Chiu, A.S, 2009. Fuzzy AHP-based study of cleaner production
implementation in Taiwan PWB manufacturer. Journal of Cleaner Production, 17(14):1249-
1256.
Turk, A.M. 2009. The benefits associated with ISO 14001 certification for construction firms:
Turkish case. Journal of Cleaner Production, 17(5):559-569.
131
Udeh, C. 1991. Contract Administration in Nigeria Proceedings of the International
Conference on Quantity Surveying and Developing World, held at ABU Zaria, Nigeria.
Udosen, J.U. & Akanni, P.O. 2010. A factorial analysis of building material wastage
associated with construction projects. Journal of Civil and Environmental Systems
Engineering, 11(2):81-90.
Ughamadu, F. 1993. Building Materials and Construction Costs in Nigeria. Construction in
Nigeria, 10(2):30-32.
USGBC LEED Green Building Rating System. (2012). Fundamental principles of Green
building and sustainable design. [Available Online].
http://www.epa.gov/statelocalclimate/documents/pdf/12_8_what_is_green_GGGC.pdf
[10 June, 2017].
Uwakweh, B.O., 2005. Effect of foremen on construction apprentice. Journal of construction
engineering and management, 131(12), pp.1320-1327.
Vatalis, K. I., Manoliadis, O., Charalampides, G., Platias, S. & Savvidis, S. 2013.
Sustainability components affecting decisions for green building Projects. Procedia
Economics and Finance. 5: 747-756.
Walliman, N. 2005. Your research project: a step-by-step guide for the first-time researcher.
Sage.
Walliman, N. 2011. Your research project: Designing and planning your work. Sage
Publications.
Walker-Morison, A., Grant, T. & McAlister, S. 2007. Strategies and Resources for Material
Selection. Environment Design Guide, Pro, 8
Wang, X. & Huang, J. 2006. The relationships between key stakeholders project
performance and project success: Perceptions of Chinese construction supervising
engineers. International Journal of Project Management, (24):253-260.
132
Warren-Myers, G. 2012. Sustainable management of real estate: is it really sustainability?
Journal of Sustainable Real Estate, 4(1):177-197.
Wastiels, L., and Wouters, I., 2009. Material knowledge for Design: The architect’s
vocabulary. In Emerging trends in Design Research, International Association of Societies of
Design Research (IASDR) Conference
WerkuKoshe, K. N., 2006. Investigating Causes of Construction Delay in Ethiopian
Construction Industries. Journal of Civil, Construction and Environmental Engineering, 1(1):
18-29.
Windapo, A. O., Ogunsanmi, O. E. & Iyagba, R. O. 2004.Modeling the determinants of the
demand for housing construction in Nigeria. In S. Ogunlana, C. Charoenngam, P. Herabat, &
B. H. W. Hadikusumo (Eds.), Proceedings of the CIB W107 & TG 23 International
Symposium on Globalization and Construction , 631-646, KlongLuang, Thailand: School of
Civil Engineering, Asian Institute of Technology.
Windapo, A., & Cattell, K. 2012. Examine the trends in building material prices: Build
Environment Stakeholders’ Perpectives. In proceeding of the joint CIB international
sysposium of W055,W065 and W089, W118,TG46,TG81 and TG84. International
conference on Construction Management Research: Management of Construction-
Research to practice 26-29 June, Montreal Canada, ISBN NO 978-2-98133550-0-0
[International conference proceedings international reference].
Windapo, A.O. & Cattell, K. 2013. The South African construction industry: perceptions of
key challenges facing its performance, development and growth. Journal of Construction in
Developing Countries, 18(2):65.
Wood, J. 2007. Synergy city: planning for high density-systematic society. Landscape and
Urban Planning, (83):77- 83.
Yang, J.B. & Ou, S.F., 2008. Using structural equation modeling to analyze relationships
among key causes of delay in construction. Canadian Journal of Civil Engineering,
35(4):321-332.
133
Yehia, S., Helal, K., Abusharkh, A., Zaher, A. & Istaitiyeh, H. 2015. Strength and durability
evaluation of recycled aggregate concrete. International journal of concrete structures and
materials, 9(2):219-239.
Yin, R.K. 2002. Applications of Case Study Research Second Edition (Applied Social
Research Methods Series (34).
Yudelson, J. 2010. What is a green building? In Sustainable Retail Development, Springer
Netherlands, 41-65.
Zainudeen, M.N., Kumari, G.R.S.P. & Seneviratne, T.K.K.S. 2010. Impact of design changes
on contractors’ cash flow. Built-Environment Sri Lanka, 8(1).
Zakeri, M., Olomolaiye, P.O., Holt, G.D. & Harris, F.C. 1996. A survey of constraints on
Iranian construction operatives' productivity. Construction Management & Economics,
14(5):417-426.
Zewdu, Z.T. and Aregaw, G.T., 2015. Causes of Contractor Cost Overrun in Construction
Projects: The Case of Ethiopian Construction Sector. International Journal of Business and
Economics Research, 4(4).
.
Zhou, C.C., Yin, G.F. & Hu, X.B. 2009. Multi-objective optimization of material selection for
sustainable products: artificial neural networks and genetic algorithm approach. Materials &
Design, 30(4):1209-1215.
134
APPENDICES: APPENDIX A – SURVEY QUESTIONAIRE
EFFECT OF BUILDING MATERIALS COST ON HOUSING DELIVERY TOWARDS
SUSTAINABILITY
Dear Sir/Madam,
PARTICIPATION IN A SURVEY
You are cordially invited to participate in this research survey which aims is to investigate the effects
of building materials cost on the delivery of affordable housing towards economic sustainability. This
study is primarily undertaken for academic purposes for a Master of Technology degree in
Construction Management at Cape Peninsula University of Technology.
All information provided in this study will be kept strictly CONFIDENTIAL.
Kindly complete the survey and return to:
Bimpe Alabi,
E-mail: alabim2010@yahoo.com
Department of Construction Management and Quantity Surveying
Mobile: +27 (0) 78 460 3649
Thanks for your cooperation and readiness to assist always.
135
Please tick as appropriate
1. I am aware that the information required by the researcher for in this
study and it is perceived as an opportunity to contribute towards
sustainable building innovation.
2. I understand my participation is voluntary and that I am permitted to
withdraw at any point in the survey.
3. I hereby endorse my participation in the research survey
Participant Date…………………Signature………………..
Name (optional)…………………………………………
Bimpe Alabi Date…………………Signature………………..
136
QUESTIONNAIRE
SECTION A: BIOGRAPHICAL INFORMATION OF PARTICIPANTS
PLEASE, cross or tick as appropriate (X or √) to indicate your opinion.
A1. Kindly indicate which best describes your company:
A2. Please indicate your gender:
Male
Female
A3. Please indicate your age group:
Below
26
26-30 31-35 36-40 41-45 46-50 51-55 56-60 61-65 65
Above
A4. Please indicate your highest formal qualification
Matric
Certificate
Diploma Bachelor’s/
Honour’s
degree
Master’s
degree
Doctorate
degree
Other (please
specify)
A5. Kindly indicate your present position in your firm……………………………………
A6. How long have you been working in this position? …………………………..………
Project management firm
Contracting firm
Materials supplier
Construction managing firm
Government establishment
Quantity Surveying consulting firm
Others (Specify)
137
A7. Kindly indicate the number of years of work experience you have………………..
SECTION B: FACTORS RESPONSIBLE FOR THE INCREASE IN THE COST OF BUILDING
MATERIALS
B1. The following are economic related factors responsible for the increase in cost of building
materials, kindly “tick as appropriate”, using the scale below.
Where: 4 = Strongly agree, 3= Agree, 2= Disagree, 1= Strong disagree,
ECONOMIC FACTORS
4 3 2 1
Exchange rate of rand
Inflation
Interest rate
Local taxes and charges
Fluctuation in the cost raw materials
Inadequate production of building materials
Supply and demand of building materials
Cost of building materials
Scarcity of building raw materials
Market condition
138
B2. The following are Building production processes related factors responsible for the increase
in cost of building materials, kindly “tick as appropriate”, using the scale below.
Where: 4 = Strongly agree, 3= Agree, 2= Disagree, 1= Strong disagree,
BUILDING PRODUCTION PROCESSES 4 3 2 1
SITE RELATED FACTORS
Poor site planning prevents easy movement of materials
Unsuitable locations for building materials storage
Wastage of building materials by labourers
Pilferage of materials on site
Inadequate infrastructural facilities
Shortage of building materials on site
Cost of fuel
HUMAN FACTORS 4 3 2 1
Cost of transportation and distribution of labour
Communication problem between labourers and supervisors
Cost of labour
Cost of power supply
Delay in payment of construction labourers
Cost of fuel
Cost of plant
Lack of discipline among labourers
DESIGN FACTORS 4 3 2 1
Design changes
Additional work due to errors in design
Additional work due to changes in design
Construction design complexity
Inadequate coordination among design team
Wrong method of estimation by quantity surveyor
Design team experience
139
B3. The following are stakeholders’ related factors responsible for the increase in cost of building
materials, kindly “tick as appropriate”, using the scale below.
Where: 4 = Strongly agree, 3= Agree, 2= Disagree, 1= Strong disagree,
STAKEHOLDERS ‘RELATED FACTORS 4 3 2 1
Delay in the supply of materials
Change initiated by contractor to improve quality
Inadequate details in drawing
Fraudulent activities
Improper planning
Client demand on high quality project delivery
Client contribution to design change
Supplier default
B4. The following are external related factors responsible for the increase in cost of building
materials, kindly “tick as appropriate”, using the scale below.
Where: 4 = Strongly agree, 3= Agree, 2= Disagree, 1= Strong disagree
EXTERNAL FACTORS 4 3 2 1
Force majeure (natural occurrences)
Weather condition
Political interference
Change in government policies and regulation
Lack of substitute for product
Level of advanced technology
Effect of rainfall on building materials
Poor nature of construction site
Increase in cost of hiring construction machineries
Government legislations
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SECTION C: EFFECTS OF INCREASE IN THE COST OF BUILDING MATERIALS ON HOUSING DELIVERY.
The following are the effects of increase in the cost of building materials on housing delivery. Kindly “tick as appropriate” the extent at which it affects delivery of affordable housing
Where 4 = To a very large extent, 3 = To a large extent, 2 = To a little extent, 1 = Not at all
EFFECTS OF INCREASE IN THE COST OF BUILDING MATERIALS ON HOUSING DELIVERY
4 3 2 1
Fluctuation in cost of construction
Unemployment of construction workers
Hindered adequate implementation of innovation in construction
Low volume of construction product
Poor quality of construction product
Increase in project abandonment
Shortage in the delivery of adequate housing to the populace
Delay on the progress of project works
Poor workmanship due to inadequate materials to use
Completion at the expense of other projects
Building collapses due to the use less quality of materials
Low income earners priced out of home ownership due to cost of building
Affect gross domestic product (GDP) contribution to the economy
High maintenance cost due to the use of less quality materials
Increase in the cost of repair due to inferior materials used
Affect the aesthetics value of building product
High rate of contractors’ fraudulent practices
Threatening health as well as safety of workers on site
Affect client expectation’s on quality project delivery
Increase in final cost of building product, final cost higher than budgeted
Transportation cost – e.g. returning sub-standard materials to the supplier
Investment return on Construction project are delayed
Conflict between client and contractors due to upward review of contract sum
141
SECTION D: CRITERIA FOR SELECTION OF SUSTAINABLE BUILDING MATERIALS
D1. The following are the stakeholders in the building industry kindly indicate how much influence
each has in materials selection. On a scale of 1 – 4
Where 4 = Very high, 3 = High, 2 = Low, 1 = Very Low
STAKEHOLDERS 4 3 2 1
Client
Architects & designers
Quantity Surveyors
Project Managers
Site Managers
Contractors
Technical consultants
Suppliers of materials
materials manufacturer
D2. The following are guidelines to materials selection in construction towards enhancing sustainable
building delivery. Kindly rate their level of effectiveness.
Where: 4 = Very Important, 3 = Important, 2 =Not Important, 1 = Less Important
GUIDELINES 4 3 2 1
Environmental impact of materials
Material market trend demands
Material life cycle cost
Material structural demands
Material functional demands
Socio economic impact of materials
Material efficiency (use of renewable and recyclable materials )
Material overview
Technological impact of materials
Building design
142
D3. The following are criteria often considered during materials selection for optimum materials
usage in relation to the sustainability categories under which they are listed. “Kindly tick as
appropriate.”
Where: 4 = Extremely Important, 3= Important, 2 = Not Important, 1 = Less Important.
SOCIO- ECONOMIC CRITERIA 4 3 2 1
Initial cost
Maintenance cost
Disposal cost
Transportation cost
Recycle cost
Health and safety
Aesthetics
Use of local materials
Labour availability
ENVIRONMENT CRITERIA 4 3 2 1
Air quality
Potential for recycling as well as re-use
Environmental pollution
Sound disposal options
Green gas emission
Energy consumption
Low or non- toxicity
Amount of likely wastage in the use of material
Ozone depletion potential
Environmental statutory compliance
Embodied energy in the material
TECHNICAL CRITERIA 4 3 2 1
Resistance to decay
Fire resistance
Maintainability
Sound insulation
Energy saving and thermal insulation
Life expectancy of material (strength, durability)
143
Material availability
Ease of construction
Moisture resistance
D3. Following are project factors determine the nature and type of materials kindly indicate as they
affected your rating of the criteria listed above. “Kindly tick as appropriate.”
Where 4 = To a very large extent, 3 = To a large extent, 2 = To a little extent, 1 = Not at all
FACTORS 4 3 2 1
Client preference
Project schedule
Stakeholder expectation
Nature of the project `
Budgeted project cost
Site condition
Complexity of project
Size of project
Scope of project
Type of project
THANK YOU VERY MUCH FOR YOUR TIME.
144
APPENDIX B: INTERVIEW QUESTIONS
1. In your own opinion, what are the factors responsible for the increase in the cost of building
materials?
2. Based on your experience, do you opine that building production processes play a role in the
cost of building materials?
• Do external factors play a role on the cost of building materials?
3. In your opinion, what are the effects of building material cost on housing delivery?
4. From your experience, what are the criteria for the selection of sustainable building
materials?
5. What guidelines need to be followed or adopted when selecting building materials?
6. In your own opinion, what measures can be taken to enhance sustainable housing delivery
with respect to the cost of building materials?
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